Solid-Phase Synthesis of 2-Benzothiazolyl and 2-(Aminophenyl)benzothiazolyl Amino Acids and Peptides

2-benzothiazoles and 2-(aminophenyl)benzothiazoles represent biologically interesting heterocycles with high pharmacological activity. The combination of these heterocycles with amino acids and peptides is of special interest, as such structures combine the advantages of amino acids and peptides with the advantages of the 2-benzothiazolyl and 2-(aminophenyl)benzothiazolyl pharmacophore group. In this work, we developed an easy and efficient method for the solid-phase synthesis of 2-benzothiazolyl (BTH) and 2-(aminophenyl)benzothiazolyl (AP-BTH) C-terminal modified amino acids and peptides with high chiral purity.

Besides Phortress, the AP-BTH scaffold has shown remarkable biological properties and is considered a potent and selective pharmacophore and a scaffold of special interest, found in many antitumor, anti-Alzheimer and anti-microbial agents [19]. In addition to these properties, the high interaction ability of 2-(aminophenyl)benzothiazole scaffolds with amyloid fibrils, clearly indicated by Thioflavin-T, has led to the synthesis of 2-(4-aminophenyl)benzothiazole decorated nanovesicles that effectively inhibit Aβ 1-42 fibril formation and exhibit in vitro brain targeting potential [26].
with amino acids and peptides is of interest, as such compounds would combine the ad vantages of BTH/AP-BTH scaffolds with the advantages of amino acids/peptides. For this suitable chemistries that would allow the easy and efficient synthesis of such compound are of great interest. In particular, the use of Solid-Phase Synthesis (SPS) as a tool for the synthesis of tile compounds would greatly simplify their synthesis and the discovery o new bioactives [38]. 2-benzothiazoles are synthesized via several methods, including the condensation o ortho-aminobenzenethiols with carboxylic acid derivatives, the radical cyclisation of thi oacylbenzanilides, or the base-induced cyclization of the corresponding ortho-haloan ilides [39,40,41]. These methods are performed in solution under conditions not appropri ate for SPS and in several cases give complex product mixtures.
Regarding the synthesis of the 2-(4-aminophenyl)benzothiazole scaffold, this i mainly achieved through the cyclization of nitro-substituted thiobenzanilides to nitro phenyl-benzothiazoles using the Jacobson synthesis and subsequent reduction, while cer tain 2-(4-aminophenyl)benzothiazoles with no substituents in the benzothiazolyl moiety are prepared via the reaction of 2-aminobenzenethiol and 4-aminobenzoic acid or benzo nitrile in polyphosphoric acid (PPA) at high temperatures (220 °C) [18]. The condensation of 2-(4-aminophenyl)benzothiazole with amino acids has been achieved by its reaction with 1-hydroxybenzotriazole activated amino acids [25]. Besides the limitations of the ap plied chemistries during 2-(4-aminophenyl)benzothiazole synthesis (high temperatures complex product mixtures, substrate dependence) and the conjugation of 2-(4-aminophe nyl)benzothiazole with 1-hydroxybenzotriazolyl amino acids (low reactivity, repeated  (1,2) and the synthesized BTH (3,4) and AP-BTH (5, 6) derivatives of these. [27][28][29][30] with broad applications in materials science, while in the diagnostic area, many metal-radiolabeled 2-phenylbenzothiazole derivatives are continuing to be explored as amyloid imaging agents [23,[31][32][33]. Non-metal-based positron emission tomography (PET) imaging of Aβ plaques is also possible through the use of radiolabeled benzothiazoles such as the 18 F-labeled derivative of 2-(4-aminophenyl)benzothiazole [ 18 F] Flutemetamol, which gained approval in 2013 for clinical use [34,35]. Based on the high interest in BTHs and AP-BTHs, several benzothiazole derivatives and hybrids have also been designed [24,36,37]. In this direction, the combination of BTH and AP-BTH scaffolds with amino acids and peptides is of interest, as such compounds would combine the advantages of BTH/AP-BTH scaffolds with the advantages of amino acids/peptides. For this, suitable chemistries that would allow the easy and efficient synthesis of such compounds are of great interest. In particular, the use of Solid-Phase Synthesis (SPS) as a tool for the synthesis of tile compounds would greatly simplify their synthesis and the discovery of new bioactives [38].

2-phenylbenzothiazoles have also shown interesting metal-involved noncovalent interactions
2-benzothiazoles are synthesized via several methods, including the condensation of ortho-aminobenzenethiols with carboxylic acid derivatives, the radical cyclisation of thioacylbenzanilides, or the base-induced cyclization of the corresponding ortho-haloanilides [39][40][41]. These methods are performed in solution under conditions not appropriate for SPS and in several cases give complex product mixtures.
In the present work we considered, for the first time, SPS as an easy and efficient approach for the synthesis of BTH amino acids and peptides (type 3 and 4, respectively), as well as the synthesis of AP-BTH amino acids and AP-BTH peptides (type 5 and 6, respectively), using resin-bound 2-aminobenzenethiol 7 (Scheme 1). This resin (7) has been effectively used by us for the SPS of 2-benzothiazolyl compounds [44]. In brief, 2-aminobenzenethiol was initially attached to trityl type resins, preferably 4-methoxytiryl (Mmt)-resin (resin 7), and this resin was further used for the synthesis of several 2-alkyl and 2-arylbenzothiazoles 9. These were obtained by the acylation of 7 with alkyl and aryl carboxylic acids, activated with N,N -diisopropylcarbodiimide (DIC), to obtain the resinbound 2-N-acyl-aminobenzenethiols 8, which, upon treatment with mild trifluoroacetic acid (TFA) solutions in dichloromethane (DCM) and triethylsilane (TES), liberated the 2-N-acyl-aminobenzenethiols, which were cyclized into the corresponding 2-substituted benzothiazoles 9 (Scheme 1). coupling cycles, high reaction times) [18,25], such methods are not appropriate for the synthesis of AP-BTH peptides where SPS or Convergent Synthesis methods are required [42,43].
In the present work we considered, for the first time, SPS as an easy and efficient approach for the synthesis of BTH amino acids and peptides (type 3 and 4, respectively), as well as the synthesis of AP-BTH amino acids and AP-BTH peptides (type 5 and 6, respectively), using resin-bound 2-aminobenzenethiol 7 (Scheme 1). This resin (7) has been effectively used by us for the SPS of 2-benzothiazolyl compounds [44]. In brief, 2-aminobenzenethiol was initially attached to trityl type resins, preferably 4-methoxytiryl (Mmt)resin (resin 7), and this resin was further used for the synthesis of several 2-alkyl and 2arylbenzothiazoles 9. These were obtained by the acylation of 7 with alkyl and aryl carboxylic acids, activated with N,N′-diisopropylcarbodiimide (DIC), to obtain the resinbound 2-N-acyl-aminobenzenethiols 8, which, upon treatment with mild trifluoroacetic acid (TFA) solutions in dichloromethane (DCM) and triethylsilane (TES), liberated the 2-N-acyl-aminobenzenethiols, which were cyclized into the corresponding 2-substituted benzothiazoles 9 (Scheme 1). Taking advantage of this method, we considered the synthesis of BTH and AP-BTH amino acids and peptides by combining this methodology with the widely used 9-fluorenylmethoxycarbonyl (Fmoc)/tert-butyl ( t Bu) strategy in Solid-Phase Peptide Synthesis (SPPS) [45]. The Fmoc/ t Bu strategy requires mild conditions and an orthogonal protection system; amino acid side chains are protected by acid-labile groups, while the alpha amine group is protected by the base-labile Fmoc group. As the most suitable resin for our synthetic approach, we selected Mmt-resin 7 [44]. This resin would allow the synthesis of the side chain fully deprotected BTH and AP-BTH amino acids/peptides upon treatment with high concentrations of TFA solutions (65-90% TFA in the presence of scavengers, i.e., TES), while upon treatment with 1.1% TFA in the presence of scavengers, the side chain protected BTH and AP-BTH amino acids/peptides could be obtained. The key point of the proposed method is the coupling of the first amino acid to resin-bound 2-aminobenzenethiol 7, due to the relatively low nucleophilicity of the aromatic amine group, thus a highly activated Fmoc-amino acid would be required. Obviously, the activating agents used for this reaction would influence not only the rate of reaction but also the degree of racemization of the first amino acid. For this, the degree of racemization of the first amino acid for BTH (and AP-BTH) amino acid derivatives (3 and 5) was measured and the results are discussed. Furthermore, in order to demonstrate the applicability of the proposed method, a series of BTH and AP-BTH amino acids/peptides (of types 4 and 6) were synthesized.

General Method Analysis
For the synthesis of BTH-amino acids (AAs) 3 and ΒΤΗ-peptides 4, resin-bound 2aminobenzenethiol 7 was initially reacted with representative Fmoc-amino acids (Leu, Scheme 1. General method for the solid-phase synthesis of alkyl and aryl 2-benzothiazolyl compounds 9. Taking advantage of this method, we considered the synthesis of BTH and AP-BTH amino acids and peptides by combining this methodology with the widely used 9-fluorenylmethoxycarbonyl (Fmoc)/tert-butyl ( t Bu) strategy in Solid-Phase Peptide Synthesis (SPPS) [45]. The Fmoc/ t Bu strategy requires mild conditions and an orthogonal protection system; amino acid side chains are protected by acid-labile groups, while the alpha amine group is protected by the base-labile Fmoc group. As the most suitable resin for our synthetic approach, we selected Mmt-resin 7 [44]. This resin would allow the synthesis of the side chain fully deprotected BTH and AP-BTH amino acids/peptides upon treatment with high concentrations of TFA solutions (65-90% TFA in the presence of scavengers, i.e., TES), while upon treatment with 1.1% TFA in the presence of scavengers, the side chain protected BTH and AP-BTH amino acids/peptides could be obtained. The key point of the proposed method is the coupling of the first amino acid to resin-bound 2-aminobenzenethiol 7, due to the relatively low nucleophilicity of the aromatic amine group, thus a highly activated Fmoc-amino acid would be required. Obviously, the activating agents used for this reaction would influence not only the rate of reaction but also the degree of racemization of the first amino acid. For this, the degree of racemization of the first amino acid for BTH (and AP-BTH) amino acid derivatives (3 and 5) was measured and the results are discussed. Furthermore, in order to demonstrate the applicability of the proposed method, a series of BTH and AP-BTH amino acids/peptides (of types 4 and 6) were synthesized. For the synthesis of BTH-amino acids (AAs) 3 and BTH-peptides 4, resin-bound 2-aminobenzenethiol 7 was initially reacted with representative Fmoc-amino acids (Leu, Glu, Lys, Arg, Ser), including the most racemization-prone amino acids Cys and His. Common protecting groups for the orthogonal protection of these AAs were selected: t Bu, (tert-butyloxycarbonyl) Boc, (trityl) Trt, (2,2,4,6,7-pentamethyldihydrobenzofuran-5sulfonyl) Pbf [46].

Results and Discussion
Thus, resin 7 was initially reacted for 3 h at rt with a five-molar excess of the Fmocamino acid in N-methyl-2-pyrrolidone (NMP) using DIC as the activating agent, leading to resin 10, which upon treatment with 25% piperidine in NMP gave the Fmoc-deprotected resin 11 (Scheme 2).

FOR PEER REVIEW 4 of 23
Glu, Lys, Arg, Ser), including the most racemization-prone amino acids Cys and His. Common protecting groups for the orthogonal protection of these AAs were selected: t Bu, (tert-butyloxycarbonyl) Boc, (trityl) Trt, (2,2,4,6,7-pentamethyldihydrobenzofuran-5-sulfonyl) Pbf [46]. Thus, resin 7 was initially reacted for 3 h at rt with a five-molar excess of the Fmocamino acid in N-methyl-2-pyrrolidone (NMP) using DIC as the activating agent, leading to resin 10, which upon treatment with 25% piperidine in NMP gave the Fmoc-deprotected resin 11 (Scheme 2). Resin 11 was further treated with TFA in DCM/TES (95:5), which allowed cleavage from the resin and formation of the BTH-amino acids 3 after cyclization of the liberated 2-N-aminoacyl-aminobenzenethiols, within 1-3 h at rt, in methanol (MeOH) (or NMP/MeOH) in the presence of dithiothreitol (DTT) (0.1-0.2 mmol) (which acts as a reducing agent for any disulfides that might be formed during the cleavage process) [44]. The use of 1.1% TFA in DCM/TES (95:5) allowed the formation of fully protected BTHamino acids, while treatment with higher concentrations of TFA (>65%) resulted in simultaneous cleavage from the resin and side-chain deprotection [46,47], allowing the formation of fully side-chain deprotected BTH-amino acids.
In case of an incomplete coupling between the first Fmoc-amino acid and resin 7 (which was easily identified by the presence of oxidized bis-2-aminothiophenol either by TLC or HPLC analysis of the cleavage mixture), a second coupling reaction was performed under the same conditions (prior to Fmoc deprotection). In case of a second incomplete coupling, the unreacted amines were blocked via acetic anhydride and N,N-diisopropylethylamine (DIPEA) through the formation of resin-bound 2-N-acetyl-aminobenzenethiol 8. In this case, 2-methylbenzothiazole (BTH-CH3) 9 was also formed upon treatment with TFA/TES and cyclization (Scheme 2). Scheme 2. General method for the solid-phase synthesis of C-modified BTH-amino acids and peptides.
Resin 11 was further treated with TFA in DCM/TES (95:5), which allowed cleavage from the resin and formation of the BTH-amino acids 3 after cyclization of the liberated 2-Naminoacyl-aminobenzenethiols, within 1-3 h at rt, in methanol (MeOH) (or NMP/MeOH) in the presence of dithiothreitol (DTT) (0.1-0.2 mmol) (which acts as a reducing agent for any disulfides that might be formed during the cleavage process) [44]. The use of 1.1% TFA in DCM/TES (95:5) allowed the formation of fully protected BTH-amino acids, while treatment with higher concentrations of TFA (>65%) resulted in simultaneous cleavage from the resin and side-chain deprotection [46,47], allowing the formation of fully side-chain deprotected BTH-amino acids.
In case of an incomplete coupling between the first Fmoc-amino acid and resin 7 (which was easily identified by the presence of oxidized bis-2-aminothiophenol either by TLC or HPLC analysis of the cleavage mixture), a second coupling reaction was performed under the same conditions (prior to Fmoc deprotection). In case of a second incomplete coupling, the unreacted amines were blocked via acetic anhydride and N,N-diisopropylethylamine (DIPEA) through the formation of resin-bound 2-N-acetyl-aminobenzenethiol 8. In this case, 2-methylbenzothiazole (BTH-CH 3 ) 9 was also formed upon treatment with TFA/TES and cyclization (Scheme 2).
Regarding the coupling efficiency of the first amino acid, it was found that the use of a five-molar excess of the first Fmoc-amino acid resulted in relatively high coupling efficiencies, with almost complete coupling reactions (80-90%) in most cases, estimated according to the relative quantification of BTH-AAs 3 and (BTH-CH 3 ) 9 in HPLC profile analysis of the fully deprotected mixture (after cleavage and cyclization; crude mixture). Fmoc-L-His(Trt)-OH was a special case, where moderate coupling yields were identified during the first coupling cycle (50-60%) with a small increment in the second coupling cycle (70-80%), and therefore, blocking the unreacted amine groups was necessary in this case.
Resin 11 was also applied in the synthesis of BTH-peptides 4 using SPPS methods and Fmoc/ t Bu protected amino acids. DIC and (1-hydroxybenzotriazole) HOBt were used as the activation system to form resin-bound peptidyl 2-aminobenzenethiol resin 12, which, upon treatment with the appropriate concentration of TFA/TES and subsequent cyclization (as previously described), resulted in either side-chain protected or deprotected BTH peptides 4 (depending on the acid strength of the cleavage mixture) (Scheme 2).

Racemization during the First Fmoc-Amino Acid Coupling with Resin 7
An important parameter in the coupling of the first amino acid (AA1) is the expected racemization of the first amino acid due to the use of DIC (with no other coupling additives) as the condensing agent. In order to estimate the degree of racemization during the reaction of the first Fmoc-amino acid with resin 7, we reacted resin 11 with Fmoc-L-Ala-OH, which resulted in the synthesis of the corresponding dipeptides H-L-Ala-L-AA1-BTH 3a-g (after on-resin treatment with 25% piperidine) ( Figure 2). These BTH-dipeptides, as well as their corresponding H-L-Ala-D-AA1-BTH diastereomers, which were also synthesized, enabled the measurement of the degree of racemization during the coupling reaction of the first amino acid.
Molecules 2023, 28, x FOR PEER REVIEW 5 of 23 efficiencies, with almost complete coupling reactions (80-90%) in most cases, estimated according to the relative quantification of BTH-AAs 3 and (BTH-CH3) 9 in HPLC profile analysis of the fully deprotected mixture (after cleavage and cyclization; crude mixture). Fmoc-L-His(Trt)-OH was a special case, where moderate coupling yields were identified during the first coupling cycle (50-60%) with a small increment in the second coupling cycle (70-80%), and therefore, blocking the unreacted amine groups was necessary in this case.
Resin 11 was also applied in the synthesis of BTH-peptides 4 using SPPS methods and Fmoc/ t Bu protected amino acids. DIC and (1-hydroxybenzotriazole) HOBt were used as the activation system to form resin-bound peptidyl 2-aminobenzenethiol resin 12, which, upon treatment with the appropriate concentration of TFA/TES and subsequent cyclization (as previously described), resulted in either side-chain protected or deprotected BTH peptides 4 (depending on the acid strength of the cleavage mixture) (Scheme 2).

Racemization during the First Fmoc-Amino Acid Coupling with Resin 7
An important parameter in the coupling of the first amino acid (AA1) is the expected racemization of the first amino acid due to the use of DIC (with no other coupling additives) as the condensing agent. In order to estimate the degree of racemization during the reaction of the first Fmoc-amino acid with resin 7, we reacted resin 11 with Fmoc-L-Ala-OH, which resulted in the synthesis of the corresponding dipeptides H-L-Ala-L-AA1-BTH 3a-3g (after on-resin treatment with 25% piperidine) ( Figure 2). These BTH-dipeptides, as well as their corresponding H-L-Ala-D-AA1-BTH diastereomers, which were also synthesized, enabled the measurement of the degree of racemization during the coupling reaction of the first amino acid.  Figure 2. BTH dipeptides 3a-3g, which were synthesized to measure the degree of racemization during the coupling reaction of the first Fmoc-amino acid with resin 7.
For this, both H-L-Ala-L-AA1-BTH and H-L-Ala-D-AA1-BTH were subjected to HPLC analysis (separately injected and as a mixture) using appropriate conditions for their complete separation, paying special attention so that no undesired peaks interfered in the integration area, thus establishing optimal methods for the separation of the two diastereomers. This allowed us to estimate the chiral purity of the synthesized BTH-dipeptides (3a-3g) via HPLC analysis of the synthesized H-L-Ala-L-AA1-BTH and subsequent integration of the two peaks: H-L-Ala-L-AA1-BTH (main diastereomer) and H-L-Ala-D-AA1-BTH (formed due to racemization). Due to the relatively low racemization values seen in most cases, in order to undisputedly evaluate the diastereomeric purity, spiking of separately synthesized H-L-Ala-D-AA1-BTH into the analyzed H-L-Ala-L-AA1-BTH was performed when needed. By this method, we were able to measure the For this, both H-L-Ala-L-AA1-BTH and H-L-Ala-D-AA1-BTH were subjected to HPLC analysis (separately injected and as a mixture) using appropriate conditions for their complete separation, paying special attention so that no undesired peaks interfered in the integration area, thus establishing optimal methods for the separation of the two diastereomers. This allowed us to estimate the chiral purity of the synthesized BTH-dipeptides (3a-g) via HPLC analysis of the synthesized H-L-Ala-L-AA1-BTH and subsequent integration of the two peaks: H-L-Ala-L-AA1-BTH (main diastereomer) and H-L-Ala-D-AA1-BTH (formed due to racemization). Due to the relatively low racemization values seen in most cases, in order to undisputedly evaluate the diastereomeric purity, spiking of separately synthesized H-L-Ala-D-AA1-BTH into the analyzed H-L-Ala-L-AA1-BTH was performed when needed. By this method, we were able to measure the degree of diastereomeric purity of the synthesized H-L-Ala-L-AA1-BTH, which determines the chiral purity of the corresponding H-L-AA1-BTH (no racemization is expected upon insertion of the second Fmoc-amino acid). The results of this investigation are summarized in Table 1. Table 1. Racemization (% D-isomer) of H-L-AA1-BTH, measured by the formation of the H-L-Ala-L-AA1-BTH and H-L-Ala-D-AA1-BTH diastereomers and HPLC analysis. As can be seen, the reaction of resin 7 with Fmoc-amino acids activated with DIC (conditions 1; Table 1) resulted in low racemization values, which were limited between 0.25% for Leu and Ser( t Bu) and 1.89% for the racemization prone Cys(Trt). In the cases of Glu( t Bu) and Lys(Boc) the racemization was 1.13% and 1.16%, respectively, while Arg(Pbf) gave a racemization of 0.41%. His(Trt) was a special case, as this amino acid resulted in considerable amounts of racemization (44.9%) when DIC was used as the condensing agent. In an effort to lower its racemization during the first amino acid coupling, we initially attempted to add DIC in a portion-wise manner to the reaction mixture; however, this practice did not significantly improve the degree of racemization (Table 1). In contrast, when 1-hydroxy-7-azabenzotriazole (HOAt)/DIC [48] was used as coupling agent, lower degrees of racemization were seen for all amino acids [Ser( t Bu) < 0.1%; Arg(Pbf) 0.32%; Glu( t Bu) 0.98%; Lys(Boc) 0.58%; Cys(Trt) 1.32%]; however, the coupling yields were relatively reduced (70-80%). In the case of His(Trt), the use of HOAt/DIC as the condensing agent gave considerably lower racemization values (7.64%); however, the coupling yield was limited to 40-50% even after two coupling cycles, and therefore blocking of the unreacted amine groups was necessary in this case. In addition, the use of O-[(cyano-(ethoxycarbonyl)methyliden)-amino]-yloxytripyrrolidinophosphonium hexafluorophosphate and tetrafluoroborate (pyOxim)/DIPEA [49] as an activating agent system for His(Trt) did not significantly lower the degree of racemization, which was measured at 24.9%, while the coupling yield was even lower (20-30% after two coupling cycles), and therefore this method of activation was not considered satisfactory, neither in terms of racemization nor in terms of coupling efficiency of the first Fmoc-amino acid with resin 7. It should be noted that all reactions and measurements were performed twice, and the measured values were found to be repeatable and consistent with those reported. Representative analytical HPLC for quantification of the degree of racemization are presented in the Supplementary File (Figures S1-S14).

Applicability in the Solid-Phase Synthesis of BTH-Amino Acid Libraries and BTH-Peptides
As the next step in this work, in order to further reveal the applicability of the proposed method in the solid-phase synthesis of BTH-amino acids and peptides, we synthesized a small BTH-amino acid library consisting of t Bu-type-protected/Fmoc-protected BTHamino acids (  The BTH-amino acid library was prepared by reacting a mixture of an equimolar amount of AcOH, Fmoc-Gly-OH, Fmoc-L-Ala-OH, Fmoc-L-Lys(Boc), Fmoc-L-Cys(Trt)-OH, and Fmoc-L-Ser( t Bu)-OH with resin 7 using DIC as the condensing agent. Cleavage from the resin with 1.1% TFA in DCM/TES (95:5) and cyclization in DTT resulted in the side-chain protected BTH-amino acid library in Scheme 3 ( Figure S15). It should be noted that 4-5% of S-Trt-deprotected BTH-Cys-H 16a was identified in the product mixture, a known result of treatment of Cys(Trt) with 1.1-1.5% TFA/TES [47,50,51].
Similarly, the BTH-peptides 19 and 20 were synthesized via use of acid labile Fmoc-L-Cys(Mmt)-OH (19) and Fmoc-L-Ser(Trt)OH (20) as the first amino acids and subsequent SPPS. Treatment of the synthesized peptidyl resins with 1.1% TFA/TES in DCM/TES (95:5) and subsequent cyclization allowed simultaneous cleavage from the resin and removal of the S-Mmt/O-Trt protecting groups, which resulted in the preparation of the corresponding BTH-Cys-peptide 19 ( Figure S17A) and BTH-Ser-peptide 20 ( Figure S17B).
It should be highlighted that 18a, 19 and 20 are side-chain protected BTH-peptides, and they all possess one free active group (18a an amine group, 19 a thiol group, 20 a hydroxyl group), which allows their further use in solid-phase or liquid phase methods for synthesis of BTH-modified peptides through fragment condensation/convergent synthesis methodologies [42,45]. A scaled-up synthetic protocol for 18, 18a and 18b (described in Section 3.3.6) resulted in high yields of the corresponding BTH-peptides, revealing the effectiveness and scalability of the proposed methods. Prompted by the positive results for BTH-amino acids/peptides and the pharmacological significance of the 2-(aminophenyl)benzothiazolyl (AP-BTH) scaffold, we considered of special interest the extension of this method for the synthesis of AP-BTH amino acids 5 and peptides 6. The key points for this synthesis would be the successful introduction of the aminobenzoic acid scaffold to resin 7, the subsequent successful introduction of the first amino acid (with low/minimum degree of racemization), and cyclization (after cleavage from the resin) into the AP-BTH scaffold.
It should be highlighted that 18a, 19 and 20 are side-chain protected BTH-peptides, and they all possess one free active group (18a an amine group, 19 a thiol group, 20 a hydroxyl group), which allows their further use in solid-phase or liquid phase methods for synthesis of BTH-modified peptides through fragment condensation/convergent synthesis methodologies [42,45]. A scaled-up synthetic protocol for 18, 18a and 18b (described in Section 3.3.6) resulted in high yields of the corresponding BTH-peptides, revealing the effectiveness and scalability of the proposed methods.

General Method-Coupling of Aminobenzoic Acids to Resin 7
Prompted by the positive results for BTH-amino acids/peptides and the pharmacological significance of the 2-(aminophenyl)benzothiazolyl (AP-BTH) scaffold, we considered of special interest the extension of this method for the synthesis of AP-BTH amino acids 5 and peptides 6. The key points for this synthesis would be the successful introduction of the aminobenzoic acid scaffold to resin 7, the subsequent successful introduction of the first amino acid (with low/minimum degree of racemization), and cyclization (after cleavage from the resin) into the AP-BTH scaffold.
For this, we initially synthesized N-Fmoc-3-aminobenzoic acid 21a and N-Fmoc-4aminobenzoic acid 21b (Scheme 4) via the reaction of commercially available 3-and 4aminobenzoic acids 20a/b with Fmoc-OSu in 10% Na2CO3/Dioxane ( 1 H, 13 C-NMR of the synthesized products 21a/b are presented in Figures S18-S21, while their analytical HPLC spectra are presented in Figures S22A and S23A). In order to condense 21a/b with resin-bound 2-aminobenzenethiol 7, we initially tested the use of a five-fold molar excess of 21a/b over 7 using DIC as the condensing agent in NMP. Unfortunately, this reaction was unsuccessful, with no condensation product identified by HPLC analysis, possibly due to the reduced reactivity of the aromatic Oacylisourea in 21a/b and reduced nucleophilicity of the aromatic amine group in resin 7, as well as the formation of the corresponding N-acylurea by-product of 21a/b (which was In order to condense 21a/b with resin-bound 2-aminobenzenethiol 7, we initially tested the use of a five-fold molar excess of 21a/b over 7 using DIC as the condensing agent in NMP. Unfortunately, this reaction was unsuccessful, with no condensation product identified by HPLC analysis, possibly due to the reduced reactivity of the aromatic O-acylisourea in 21a/b and reduced nucleophilicity of the aromatic amine group in resin 7, as well as the formation of the corresponding N-acylurea by-product of 21a/b (which was finally identified in the reaction mixture through HPLC and ESI-MS analysis) due to the so-called O,N-acyl migration [52]. The use of HOAt as an additive did not improve the reaction yield, and no product was identified in this case either.
As an alternative route, we considered the formation of the corresponding acyl chlorides of 21a/b. Therefore, we initially tested the reaction of 21a/b with thionyl chloride (SOCl 2 ) in toluene or DCM. Unfortunately, the reaction did not proceed with either of these two solvents, possibly due to the very low solubility of 21a/b (in both solvents 21a/b were not dissolved/did not react even after prolonged reaction times). However, when the reaction solvent was changed to THF, 21a/b were completely soluble and we were able to prepare acyl chlorides 22a/b after overnight reaction at rt by the use of a five-fold molar excess of SOCl 2 relative to 21a/b (Scheme 5A). It should be noted that the chlorination reaction proceeded at a slow reaction rate, and a second five-molar excess of SOCl 2 was needed to complete chlorination . The reaction rate was easily followed using TLC and/or HPLC analysis to detect the formation of the corresponding methyl ester after quenching the reaction mixture with MeOH (analytical HPLC of 21a/b and the corresponding methyl esters are presented in Figures S22A,B and S23A,B). In order to further react acyl chlorides 22a/b with resin 7, the reaction mixture was condensed until an oily product was formed. This was re-dissolved in toluene and further condensed using three vacuum distillation cycles to completely remove excess SOCl 2 , until a white solid (22a/b) was finally formed. This was initially dissolved in DCM and then added to resin 7, which was pre-suspended in DCM and DIPEA, to afford 28 (which was identified by the formation of 29 (Scheme 6)). As the next step in our synthetic approach, the activated 21a/b were reacted with resin 7 in the presence of DIPEA at rt to form 28 (Scheme 6) and the corresponding Fmocdeprotected 30. It should be noted that when activation was carried out with SOCl2 (1.02 eq) and 5% NMP (Method B), the synthesis of 28 (and 30) was greatly simplified, compared with the activation of 21a/b with excess SOCl2 (in the absence of NMP), as no extra work-up was needed and therefore the formation of AP-BTH 29 proceeded using this protocol with exceptional ease and purity (Figures S22D and S23D). To further ensure the efficacy of the proposed protocol, 2-(4-aminophenyl)benzothiazole (4-AP-BTH; 31a) and

Racemization during the First Fmoc-Amino Acid Coupling to Resin 30
Based on the positive results from the reaction of Fmoc-amino acids with resin 7 (Section 2.1.2), as well as the low degree of racemization measured during the first coupling even when only DIC was used as the condensing agent (Section 2.1.2; Table 1), we considered the same approach as a method to couple the first amino acid to resin-bound 2-Naminobenzoyl-aminobenzenethiol 30 (Scheme 6). Thus, resin 30 was reacted with Fmocamino acids in NMP using DIC as the condensing agent, which resulted in the formation of 32. Removal of the N-Fmoc group with 25% piperidine in NMP gave, after treatment with TFA/TES, the corresponding AP-BTH amino acids 5. In addition, SPPS methods afforded AP-BTH peptides 6 after acidic treatment with TFA/TES of the synthesized resin 33 (Scheme 6).
In order to measure the degree of racemization during the coupling of the first Fmocamino acid with resin 30, we considered Fmoc-L-Arg(Pbf)-OH, Fmoc-L-Lys(Boc)-OH, Fmoc-L-Glu( t Bu)-OH, Fmoc-L-Cys(Trt)-OH and Fmoc-L-His(Trt)-OH as representative amino acids (also used for the BTH-AAs racemization study, Section 2.1.2). The degree of racemization, which reflects the chiral purity of the synthesized AP-BTH amino acids, was evaluated through formation of the diastereomeric dipeptides H-L-Ala-L-AA1-AP-BTH and H-L-Ala-D-AA1-AP-BTH according to HPLC analysis (as clearly described in Section 2.1.2). In the case of Cys, separation of the two diastereomers was achieved through the synthesis of the tripeptide H-L-Lys-L-Ala-L-Cys-AP-BTH (and the corresponding H-L-Lys-L-Ala-D-Cys-AP-BTH). The structures that were synthesized for this study are shown in Figure 3, while analytical HPLC profiles measuring the degree of racemization are presented in the Supplementary File ( Figure S28-S37). The results are presented in Table 2. In an effort to simplify the chlorination process, we considered another method for the activation of 21a/b based on the reaction of 21a/b with SOCl 2 in THF or DCM using 5% NMP (v/v) as catalyst. In fact, the addition of 5% NMP to the reaction mixture of 21a and SOCl 2 (1.02 eq) in DCM resulted in fast activation of 21a (less than 5 min at rt) (evidenced by the fast dissolution of 21a, initially insoluble in DCM), also proved by quenching a small sample of the activated 21a with MeOH, which resulted in the formation of the corresponding methyl ester. The effective activation of 21a in the presence of NMP was easily followed with HPLC analysis, where the HPLC profile of the reaction of 21a with SOCl 2 in DCM before the addition of NMP ( Figure S22A) showed the existence of only 21a, while 5 min after the addition of 5% NMP (v/v), quenching of the reaction mixture with MeOH resulted in the formation of the corresponding methyl ester ( Figure S22C) (a clear indication of the successful activation of 21a).
It should be noted that the activation of 21b using an equimolar amount of SOCl 2 (1.02 mmol) and 5% NMP required longer reaction times compared with 21a. In fact, the activation of 21b was performed in THF/DCM (2:1), wherein the effective activation of 21b, when NMP was added to the reaction mixture, was completed in 20-30 min at rt. The effective activation of 21b in the presence of NMP was also confirmed by HPLC analysis, where the initial 21b ( Figure S23A) was completely converted into the corresponding methyl ester by quenching a sample of the reaction mixture with MeOH ( Figure S23C).
As an explanation of the fast activation of 21a/b in the presence of NMP, in contrast to the very slow chlorination reaction in absence of NMP, we considered the catalytic activity of NMP, as evidenced by the fast activation of 21a/b when NMP was added to the reaction mixture, and therefore we propose the mechanism in Scheme 5B. Although the proposed mechanism has not yet been clarified, NMP has been proposed as a catalyst for the reaction of carboxylic acids with SOCl 2 , possibly through the formation of 23, leading to the Vilsmeier complex 24 and/or 26 [53][54][55][56][57][58][59] /or 27). Although this is a proposed mechanism, the presence of 25 and/or 27 and/or 22, through the catalytic activity of NMP, is proved by the fast activation of 21a/b only when NMP is added to the chlorination mixture. In any case, this procedure allowed the fast activation of the carboxylic acid group of 21a/b (as confirmed by the fast reaction of the activated 21a/b with excess MeOH yielding the corresponding methyl esters).
As the next step in our synthetic approach, the activated 21a/b were reacted with resin 7 in the presence of DIPEA at rt to form 28 (Scheme 6) and the corresponding Fmocdeprotected 30. It should be noted that when activation was carried out with SOCl 2 (1.02 eq) and 5% NMP (Method B), the synthesis of 28 (and 30) was greatly simplified, compared with the activation of 21a/b with excess SOCl 2 (in the absence of NMP), as no extra work-up was needed and therefore the formation of AP-BTH 29 proceeded using this protocol with exceptional ease and purity ( Figures S22D and S23D). To further ensure the efficacy of the proposed protocol, 2-(4-aminophenyl)benzothiazole (4-AP-BTH; 31a) and 2-(3-aminophenyl)benzothiazole (3-AP-BTH; 31b) (Scheme 6) were also obtained through the acidic treatment of resin 30 and subsequent cyclization (the procedure is analytically described in Section 3.3.6). Both products were obtained in high yield (>90%) and purity ( Figures S24-S27).

Racemization during the First Fmoc-Amino Acid Coupling to Resin 30
Based on the positive results from the reaction of Fmoc-amino acids with resin 7 (Section 2.1.2), as well as the low degree of racemization measured during the first coupling even when only DIC was used as the condensing agent (Section 2.1.2; Table 1), we considered the same approach as a method to couple the first amino acid to resin-bound 2-N-aminobenzoyl-aminobenzenethiol 30 (Scheme 6). Thus, resin 30 was reacted with Fmoc-amino acids in NMP using DIC as the condensing agent, which resulted in the formation of 32. Removal of the N-Fmoc group with 25% piperidine in NMP gave, after treatment with TFA/TES, the corresponding AP-BTH amino acids 5. In addition, SPPS methods afforded AP-BTH peptides 6 after acidic treatment with TFA/TES of the synthesized resin 33 (Scheme 6).
In order to measure the degree of racemization during the coupling of the first Fmocamino acid with resin 30, we considered Fmoc-L-Arg(Pbf)-OH, Fmoc-L-Lys(Boc)-OH, Fmoc-L-Glu( t Bu)-OH, Fmoc-L-Cys(Trt)-OH and Fmoc-L-His(Trt)-OH as representative amino acids (also used for the BTH-AAs racemization study, Section 2.1.2). The degree of racemization, which reflects the chiral purity of the synthesized AP-BTH amino acids, was evaluated through formation of the diastereomeric dipeptides H-L-Ala-L-AA1-AP-BTH and H-L-Ala-D-AA1-AP-BTH according to HPLC analysis (as clearly described in Section 2.1.2). In the case of Cys, separation of the two diastereomers was achieved through the synthesis of the tripeptide H-L-Lys-L-Ala-L-Cys-AP-BTH (and the corresponding H-L-Lys-L-Ala-D-Cys-AP-BTH). The structures that were synthesized for this study are shown in Figure 3, while analytical HPLC profiles measuring the degree of racemization are presented in the Supplementary File (Figures S28-S37). The results are presented in Table 2.
As can be seen in Table 2, the reaction of the first Fmoc-amino acid with resin 30 using DIC as the activating agent proceeded with considerably low racemization, where Arg(Pbf), Glu( t Bu) and Lys(Boc) showed exceptionally low racemization (<0.25%), while the racemization of Cys(Trt) was measured at 1.08%. H-His(Trt)-AP-BTH behaved similarly with H-His(Trt)-BTH (Section 2.1.2; Table 1) and therefore the initial degree of racemization of 44.5% (when DIC was used as the condensing agent) was finally limited to 7.65% (when HOAt/DIC was used as the condensing agent). It should be noted that all reactions and measurements were performed twice, and the measured values were found to be repeatable and consistent with those reported.  Figure 3. AP-BTH peptides (34)(35)(36)(37)(38) synthesized to measure the degree of racemization during the coupling reaction of the first Fmoc-amino acid with resin 30.

AA1
Rac% 1 Rac% 2 Arg(Pbf) 0.14 Glu( t Bu) 0.23 Lys(Boc) <0.10 Cys(Trt) 3 1.08 His(Trt) 44.5 7.65 As can be seen in Table 2, the reaction of the first Fmoc-amino acid with resin 30 using DIC as the activating agent proceeded with considerably low racemization, where Arg(Pbf), Glu( t Bu) and Lys(Boc) showed exceptionally low racemization (<0.25%), while the racemization of Cys(Trt) was measured at 1.08%. H-His(Trt)-AP-BTH behaved similarly with H-His(Trt)-BTH (Section 2.1.2; Table 1) and therefore the initial degree of racemization of 44.5% (when DIC was used as the condensing agent) was finally limited to 7.65% (when HOAt/DIC was used as the condensing agent). It should be noted that all reactions and measurements were performed twice, and the measured values were found to be repeatable and consistent with those reported.

Applicability in the Solid-Phase Synthesis of AP-BTH Peptides
As a proof of concept, besides the racemization study, we also synthesized a small series of AP-BTH peptides (39-43;

Applicability in the Solid-Phase Synthesis of AP-BTH Peptides
As a proof of concept, besides the racemization study, we also synthesized a small series of AP-BTH peptides (39-43; Figure 4). AP-BTH peptides 40 and 41 contain the 3-AP-BTH scaffold, while 39, 42 and 43 contain the 4-AP-BTH scaffold. For the synthesis of 39, 40, and 42, which are side-chain-protected AP-BTH peptides, the corresponding resins were treated with 1.1% TFA/TES, while for the synthesis of side-chain deprotected AP-BTH peptides 41 and 43, the resins were treated with TFA/DCM/TES (90/5/5).
All AP-BTH peptides (39)(40)(41)(42)(43) were synthesized in high purity (the analytical HPLC spectra are presented in Figure S38), while their expected structures were successfully identified using ESI-MS. In addition, scaled-up synthesis of 42 and 43 (described in Section 3.3.6) gave high yields for both products, revealing the effectiveness and scalability of the method.  Figure 4. AP-BTH tripeptides of type 6 that were synthesized.
All AP-BTH peptides (39)(40)(41)(42)(43) were synthesized in high purity (the analytical HPLC spectra are presented in Figure S38), while their expected structures were successfully identified using ESI-MS. In addition, scaled-up synthesis of 42 and 43 (described in Section 3.3.6) gave high yields for both products, revealing the effectiveness and scalability of the method.

Analytical Methods
Thin layer chromatography (TLC) was performed on precoated silica gel 60 F254 plates (Merck, Darmstadt, Germany) and spot detection was carried out using UV light and/or by charring with a ninhydrin solution. High Performance Liquid Chromatography

Analytical Methods
Thin layer chromatography (TLC) was performed on precoated silica gel 60 F 254 plates (Merck, Darmstadt, Germany) and spot detection was carried out using UV light and/or by charring with a ninhydrin solution. High Performance Liquid Chromatography (HPLC) analysis was performed on a Waters 2695 multisolvent delivery system (Milford, MA, USA), combined with a Waters 991 photodiode array detector. The following columns were 4-Aminobenzoic acid 20a (or 3-aminobenzoic acid 20b) (0.0146 mmol; 2 g) was placed in a round-bottom flask and the solid was dissolved in a mixture of dioxane and aq. 10% Na 2 CO 3 (1:1) (40 mL). The mixture was kept under stirring at rt. To the resulting solution, N-(9-fluorenylmethoxycarbonyloxy)succinimide (Fmoc-OSu) (0.0160 mmol; 5.41 g) dissolved in 20 mL dioxane was slowly added and the pH of the reaction was periodically adjusted to around 8.0-9.0 using aq. 10% Na 2 CO 3 . The reaction mixture was further stirred overnight at rt, where a gradual increase in the formation of a white precipitate (21a/b) was observed. The reaction progress and completion was monitored via TLC analysis (until all starting materials 20a/b were reacted). Then, ethyl acetate (EtOAc) was added (40 mL) and to this mixture conc. HCl was slowly added until reaching pH 2.0. The two phases were separated, and the aqueous phase was washed twice with EtOAc. The combined organic phases were washed with water (3 × 50 mL) and the organic phase was concentrated into a rotary evaporator, where a white solid was formed. This was obtained by washing with diethyl ether (DEE) (3 × 50 mL) and drying in vacuo. Yield: 21a (3.93 g; 75%); 21b (3.56 g; 68%). Purity: 21a (>98%); 21b (>98%) based on HPLC analysis (265 nm). 21a: 1 H-NMR δ (600 MHz, DMSO-d 6

Solid-Phase Synthesis-General Protocols
Solid-phase peptide synthesis was carried out manually either in plastic reactors for peptide synthesis (polypropylene syringes equipped with porous polyethylene frits at the bottom) with a pore size of 25 µm (obtained from Carl Roth Gmbh + Co. KG, Karlsruhe, Germany), attached to a Visiprep Solid Phase Extraction Vacuum Manifold, or in eppendorfs (where the reaction mixture was transferred to microfilters for washing).

Coupling of the First Fmoc-Amino Acid with Resins 7 and 30
(a) Activation with DIC The appropriate Fmoc-amino acid (0.5 mmol) was dissolved in a minimum amount of NMP (5 mL/g resin; 1.0 mL) and cooled at 4 • C for 15 min. To this solution DIC (0.55 mmol; 86.12 µL) was added and the mixture was vortexed for 1 min and added to the pre-swollen resin (0.5 mmol/g; 0.1 mmol available amine groups; 0.2 g). The resin was gently agitated for 3 h at rt and then washed with NMP (×5). In cases of incomplete coupling (determined by washing a small quantity of the resin and performing TLC and/or HPLC analysis, where bis-2-aminobenzenethiol was identified) recoupling was performed via the same procedure with fresh reagents. Any unreacted amine groups were capped using DIPEA (0.33 mmol; 57.48 µL) and acetic anhydride (Ac 2 O) (0.3 mmol; 28.36 µL) in NMP (5 mL/g; 1.0 mL) for 3 h at rt. Finally, the resin was washed with NMP (×5), iPrOH (×3), DEE (×2) and dried in vacuo.
(b) Activation with HOAt/DIC The appropriate Fmoc-amino acid (0.5 mmol) and HOAt (0.55 mmol; 0.075 g) were dissolved in a minimum amount of NMP (5 mL/g resin; 1.0 mL) and cooled at 4 • C for 15 min. Then, DIC (0.5 mmol; 78.29 µL) was added and the mixture was stirred for 20 min at 4 • C and then added to the pre-swollen resin (0.5 mmol/g; 0.1 mmol available amine groups; 0.2 g), and the resin was gently agitated for 4 h at rt and then washed with NMP (×5). In cases of incomplete coupling (as determined by TLC and/or HPLC analysis, where bis-2-aminobenzenethiol was identified) recoupling was performed via the same procedure. Any unreacted amine groups were capped using DIPEA (0.33 mmol; 57.48 µL) and Ac 2 O (0.3 mmol; 28.36 µL) in NMP (5 mL/g; 1.0 mL) for 3 h at rt. Finally, the resin was washed with NMP (×5), iPrOH (×3), and DEE (×2) and dried in vacuo.

Coupling of 21a/b with 2-Aminobenzethiol-4-methoxytrityl Resin
21a/b (0.301 mmol; 0.108 g) were dissolved in tetrahydrofuran (THF) (1.0 mL), and then thionyl chloride (SOCl 2 ) (5 eq; 1.504 mmol; 109.22 µL) was added and the reaction mixture was stirred at rt. After 3 h, a second amount of SOCl 2 (109.22 µL) was added and the reaction mixture was stirred overnight until completion of chlorination. The reaction progress was followed using TLC and HPLC analysis by taking a small sample of the reaction mixture, which was then quenched with MeOH to form the corresponding 21a/b methyl ester. Completion of the reaction was monitored according to the full conversion of 21a/b to the corresponding methyl ester. Then, the chlorination reaction mixture was concentrated until an oily product was formed. This was further dissolved in toluene and removed for three vacuum distillation cycles to completely remove excess SOCl 2 until a white solid (22a/b) was formed. This was initially dissolved in DCM, and then added to resin 7 (0.5 mmol/g; 0.2 g), which was suspended in a minimum volume of DCM and DIPEA (0.451 mmol; 78,58 µL). The resin was agitated for 3 h at rt, and then it was filtered and washed with NMP (×5), iPrOH (×3), and DEE (×2) to afford 28 (which was identified by the formation of 29).
(b) Activation of 21a/b using SOCl 2 in THF/5% NMP AND coupling with resin 7 21a (0.301 mmol; 0.108 g) was dissolved in DCM (or THF) (1.0 mL) and SOCl 2 (0.307 mmol; 22.28 µL) was added. To this solution, NMP (5% v/v; 50 µL) was added and the reaction mixture was stirred for 5 min at rt. To confirm the activation of 21a, TLC and HPLC analysis were used by taking a small sample of the reaction mixture, which was quenched with MeOH to form the corresponding 21a methyl ester.
For the activation of 21b (0.301 mmol; 0.108 g), this was dissolved in a mixture of THF/DCM (2:1) (1.5 mL), and then SOCl 2 (0.307 mmol; 22.28 µL) was added. To this, NMP (5% v/v; 50 µL) was added and the reaction mixture was stirred for 30 min at rt. The successful activation of 21b was also confirmed through TLC and HPLC analysis by taking a small sample of the reaction mixture, which was quenched with MeOH to form the corresponding 21b methyl ester.
The activated 21a/b were added to resin 7 (0.5 mmol/g; 0.2 g), which was pre-swollen with the minimum amount of DCM, and also contained the appropriate amount of DIPEA (0.451 mmol; 78.58 µL). The resin was agitated for 3 h at rt, and then it was filtered and washed with NMP (×5), iPrOH (×3), and DEE (×2) to afford 28 (which was identified by the formation of 29).

Coupling of Fmoc-Amino Acids with HOBt/DIC-Peptide Assembly
The appropriate Fmoc-amino acid (0.3 mmol) and HOBt (0.45 mmol) were dissolved in NMP (0.5 mL) and the mixture was cooled at 4 • C for 15 min. Then, DIC (0.36 mmol) was added and the mixture was agitated for 15 min at 4 • C, and further added to the resin-bound amino acid or peptide (0.1 mmol). The resin was agitated for 3 h at rt. After this time, the completion of the reaction was checked via the Kaiser test. Briefly, a sample of the resin was taken and washed with NMP, iPrOH, and DEE several times and then transferred to a small glass tube where 2 drops of each of the Kaiser solutions was added and the glass was heated to 120 • C for 4-5 min. A positive Kaiser (blue resin beads) was an indication of incomplete coupling, while a negative Kaiser test (colorless/yellowish beads) was an indication of complete coupling. In cases of incomplete coupling, recoupling was performed with a fresh solution of activated Fmoc-amino acid. Finally, the resin was filtered and washed with NMP (×5), iPrOH (×3), and DEE (×2) and dried in vacuo.

Fmoc Removal during Solid-Phase Peptide Assembly
Resin-bound Fmoc-protected amino acids or peptides were initially washed with NMP (6 mL/gr) (5 times) and then treated with 25% piperidine in NMP (6 mL/gr) for 30 min at rt (twice). To check the completion of Fmoc removal, two tests were applied. Initially, a positive Kaiser test indicated removal of the Fmoc group, while to be sure that all Fmoc has been removed, a second test was performed where a resin probe (approx. 2 mg) was treated with 25% piperidine in NMP (20 µL) and the resin was heated for 5 min at 100 • C. From the resulting solution 10 µL were spotted onto a TLC plate and run a few centimeters (and checked under a UV lamp for any UV-absorbing material). In cases of Fmoc absorbance, the deprotection was repeated for another 30 min. Finally, the resin was filtered and washed with NMP (×5), iPrOH (×3), and DEE (×2) and dried in vacuo.  9, 13, 14, 15, 16, 16a, 17, 18, 19, 20, 39, 40, 42) Resin-bound t Bu-protected/Fmoc-protected derivatives were pre-treated with 0.1% TFA in DCM (×2) and the filtrates were discarded. Then, the resin was treated with 1.1% TFA in DCM/TES (95:5) for 15 min at rt and the cleavage mixture was filtered and further washed twice with a fresh cleavage mixture. The combined filtrates were concentrated on a rotary evaporator until an oily product was formed, and then two methods were developed: (a) The oily products (fully protected derivatives) were dissolved in MeOH and DTT (0.1-0.2 eq) was added, and the mixture was stirred for 1-3 h at rt to allow cyclization into BTH and AP-BTH amino acid/peptide derivatives (completeness of cyclization was monitored using HPLC analysis). Then, MeOH was removed and the oily product that was formed was washed with either DEE or a mixture of DEE/hexane (Hex) (or Hex), and the product was dried in vacuo. (b) The oily products (fully protected derivatives) were dissolved in MeOH (or NMP/MeOH 3:1) and DTT (0.1-0.2 eq) was added, to allow cyclization to BTH and AP-BTH amino acid/peptide derivatives for 1-3 h at rt (completeness of cyclization was monitored using HPLC analysis). Then, MeOH was concentrated and the resulting solution was extracted with water and EtOAc. The two phases were separated, and the aqueous phase was washed once more with EtOAc. The combined organic phases were washed twice with water and then dried with magnesium sulfate (MgSO 4 ). The filtrates were condensed and the oily product that was formed was washed with either DEE or a mixture of DEE/Hex (or Hex), and the product was dried in vacuo. Resin-bound t Bu-protected/Fmoc-deprotected derivatives were treated with TFA/DCM/TES (90:5:5) for 15 min at rt, the cleavage mixture was filtered, and the resin was washed twice with a fresh cleavage mixture. The combined filtrates were kept under stirring for 1-3 h to allow full deprotection of the side-chain protecting groups and then concentrated on a rotary evaporator. Then, depending on the solubility of the products in organic solvents/aqueous phase, two methods were applied: (a) The oily products (fully deprotected derivatives) were dissolved in MeOH and DTT (0.1-0.2 eq) was added, and the mixture was stirred for 1-3 h at rt to allow cyclization into BTH and AP-BTH amino acid/peptide derivatives (completeness of cyclization was monitored by HPLC analysis). Then, MeOH was removed and the oily product that was formed was washed with either DEE or a mixture of DEE/Hex (or Hex), and the product was dried in vacuo. (b) The oily products (fully deprotected derivatives) were dissolved in NMP/MeOH (2:1; 3:1) and DTT (0.1-0.2 eq) was added to allow cyclization into BTH and AP-BTH amino acid/peptide derivatives for 1-3 h at rt (completeness of cyclization was monitored using HPLC analysis). MeOH was then concentrated with a flash of nitrogen and the resulting solution was extracted with water and EtOAc. The two phases were separated, and the aqueous phase was washed twice with EtOAc. TLC analysis showed that all BTH and AP-BTH amino acids/peptides tested were collected in the aqueous phase, which was finally lyophilized to afford BTH/AP-BTH amino acid/peptides. were dissolved in NMP (6 mL/gr resin; 1.2 mL) and the resulting mixture of reactants was cooled at 4 • C. Then, DIC (0.66 mmol; 103.34 µL) was added and the mixture was vortexed for 1 min and added to the pre-swollen resin 7 (0.5 mmol/gr; 0.1 mmol available amine groups; 0.2 g). The resin was agitated gently for 3 h at rt and then washed with NMP (×5), iPrOH (×3), and DEE (×2) and dried in vacuo. Cleavage and subsequent cyclization from the resin with protocol 3.3.4.1 resulted in the formation of the BTH-AAs library, which was directly subjected to HPLC analysis (crude mixture).

Scale-Up Protocols Synthesis of BTH-Peptides 18, 18a and 18b
Resin 7 (0.5 mmol/g resin; 0.25 mmol; 0.5 g) was subjected to SPS using Fmoc-Gly-OH (0.75 mmol; 0.223 g), Fmoc-L-Glu( t Bu)-OH (0.75 mmol; 0.319 g), Fmoc-L-Ala-OH (1.5 mmol; 0.234 g), and Fmoc-L-Asp( t Bu)-OH (1.5 mmol; 0.309 g) using protocol 3.3.3.1a for the coupling of the first amino acid, and then protocol 3.3.3.3 for the peptide assembly. Fmoc removal during peptide synthesis and at the end of the synthesis was accomplished using protocol 3.3.3.4. The activation of the first Fmoc-amino acid (Fmoc-Gly-OH) during the coupling reaction with resin 7 was performed using DIC (0.825 mmol; 129.17 µL) as the activating agent. This step was performed twice and resulted in complete coupling of the free amine groups, and therefore no capping of any unreacted amine groups in resin 7 was necessary. The next couplings (with Fmoc-L-Glu( t Bu)-OH, Fmoc-L-Ala-OH, Fmoc-L-Asp( t Bu)-OH) were performed using HOBt (1.125 mmol; 0.152 g) and DIC (0.9 mmol; 140.92 µL) as a mixture of activating agents. At the end of the peptide assembly (before the final Fmoc deprotection) the resin was washed with NMP (×5), iPrOH (×3), and DEE (×2) and dried in vacuo and the resin was weighted to have a mass of 0.73 g, indicating a mass increment of 0.23 g (which corresponds to a resin substitution of 0.445 mmol peptide/g resin based on mass increment, in good agreement with the initially calculated substitution of 2-aminobenzenethiol in resin 7). The purity of synthesis was evaluated by taking a small sample of the resin, which was cleaved through protocols 3.3.4.1.a and 3.3.4.1.b to afford the side-chain t Bu-protected/Fmoc-protected BTH-peptide 18, which was subjected to HPLC analysis (purity >96% according to HPLC analysis; 265 nm; Figure S16A). Then, the resin was treated with 25% piperidine (protocol 3.3.3.4) to remove the N-terminal Fmoc group and the resin was washed with NMP (×5), iPrOH (×3), and DEE (×2) and dried in vacuo. To isolate 18a, the resin was initially treated with 0.1% TFA in DCM (these filtrates were discarded) and then treated with 1.1% TFA in DCM/TES (95:5) for 15 min at rt (twice), and the filtrates were collected and concentrated until an oily product was formed. This was dissolved in MeOH and DTT (0.2 eq; 0.1 mmol; 15.4 mg) was added and the mixture was stirred for 3 h at rt. Then, MeOH was concentrated, and DEE was added to the oily product to afford a white solid which was further washed with DEE (×3) to finally obtain 18a as a white solid ( Figure S16B). Finally, 18a was further treated with TFA/DCM/TES 90/5/5 for 1 h and then concentrated to an oily residue. To this, DEE was added and the resulting solid was washed with DEE (×3) to finally obtain 18b as a white solid in high purity (>97%; 254 nm; Figure S16C). Total yield of 18b: (93.52 mg; 78%).

Conclusions
In this work, we describe for the first time the solid-phase synthesis (SPS) of C-terminal modified 2-benzothiazolyl (BTH) (3, 4) and 2-(aminophenyl)benzothiazolyl (AP-BTH) amino acids and peptides (5,6). The synthesis of 3, 4 was achieved using resin-bound 2-aminobenzenethiol (7), which was efficiently coupled with Fmoc-amino acids using DIC (or HOAt/DIC) as the condensing agent. Removal of the Fmoc group and subsequent cleavage from the resin through acidic treatment and cyclization (in the presence of DTT) resulted in the preparation of C-modified BTH amino acids 3, whereas, when SPPS methods were applied, the corresponding C-modified BTH peptides 4 were formed. The synthesis of C-terminal modified 2-(3-aminophenyl)benzothiazolyl and 2-(4-aminophenyl)benzothiazolyl (AP-BTH) amino acids 5 and peptides 6 was achieved by initially introducing the 3-aminobenzoic acid and 4-aminobenzoic acid skeleton to resin-bound 2-aminobenzenethiol (7). This was easily carried out via the chlorination of Fmoc-3-aminobenzoic acid (21a) and Fmoc-4-aminobenzoic acid (21b) with SOCl 2 in the presence of NMP as catalyst, and the coupling of 21a/b with resin 7. Removal of the Fmoc group and coupling of the first amino acid (using DIC or HOAt/DIC) and SPPS, followed by cleavage from the resin and cyclization, gave the desired AP-BTH amino acids 5 and peptides 6. The reactions proceeded with considerable purity, while the low degree of racemization that was measured during the coupling of the first Fmoc-amino acid to resinbound 2-aminobenzenethiol 7 and resin-bound 2-N-aminobenzoyl-aminobenzenethiol 30, reveals the effectiveness of the proposed methods for the synthesis of C-terminal BTH and AP-BTH amino acids and peptides.

Data Availability Statement:
The data presented in this study are available on request from the corresponding author.