Total Synthesis and Anti-HIV Activity Evaluation of Desmosdumotin D and Analogues

: The natural product Desmosdumotin D (hereafter referred to as Des-D ), isolated from the plant Desmos dumosus , showed potent anti-HIV activity. However, the subsequent pharmacological activity and clinical studies are limited due to the low content of Des-D in the plant. Therefore, the total synthesis path of Des-D was optimized in this paper, and the total yield was increased from 4.4% to 11.9%. Additionally, twelve analogues were obtained following the synthesis route of Des-D . The anti-HIV activity evaluation results in vitro showed that Des-D had the highest activity, with an IC 50 value of 13.6 µ M, and compounds 17 and 11 had the lowest anti-HIV activity, with IC 50 values of 101.3 µ M and 161.0 µ M, respectively. Through the molecular docking of compounds Des-D and 17 with HIV-IN, the results show that phenolic hydroxyl groups and two benzene rings interact with HIV-IN and are possible pharmacodynamic groups.


Introduction
The AIDS pandemic has been a serious medical and public health problem for nearly half a century.AIDS, acquired immunodeficiency syndrome (AIDS), is a systemic disease caused by body infection with the human immunodeficiency virus (HIV) [1].HIV is a lentivirus, a type of retrovirus that infects cells of the human immune system [2].Currently, the essential treatment for AIDS is highly effective antiretroviral therapy, commonly known as cocktail therapy, which combines several antiretroviral drugs to improve the quality of survival and prolong the life span of infected patients by inhibiting HIV replication and rebuilding and maintaining the body's immune function [3].Among the antiretroviral drugs, integrase inhibitors could inhibit the replication process of the retrovirus and block the integration of viral DNA and host chromosome DNA [4].Raltegravir has the characteristics of a rapid and efficient antiviral, showing good curative effects compared with traditional antiviral drugs; however, it has its own shortcomings, and antiviral drugs have certain toxic and side effects [5,6].
Natural products are often used as lead compounds in developing new drugs due to their unique chemical structure, good pharmacological activity and low toxicity, and natural products with anti-HIV activity are studied [7].Des-D (Figure 1) was first discovered in 1976 by Joshi et al. [8] from the plant Unona lawii, which belonged to the chalcone class.In 1999, Wu et al. [9,10] isolated Des-D from the roots of the domestic genus Pseudohawpaw of Phyllanthaceae family in China, which was found to have significant inhibitory activity against HIV.
of Phyllanthaceae family in China, which was found to have significant inhibitory activity against HIV.However, due to the extremely low content of Des-D, i.e., 0.04 ‱, in the plant [10], the synthesis of Des-D exhibited great potential and low cost, which could help to obtain enough products for subsequent biological activity studies.Nakagawa-Goto and Lee reported the total synthesis of Des-D first, showing a short route without the use of any protecting groups (Figure 2) [11].However, the high cost of this route could make the product uneconomical.Additionally, the instability of the reagent NaBH3CN and the relatively harsh reaction conditions could lead to poor efficiency and a low yield for the synthesis of Des-D.Due to the complex by-products and difficult purification process, the total yield was only 4.4% for the six steps, which posed difficulties for their massive synthesis [12].
Therefore, in this study, the synthesis of Des-D was optimized, and the total yield was further increased to 11.9% by using cheap starting materials, convenient reaction reagents, and a simplified separation and purification process.Meanwhile, 12 analogues were obtained by structural modification of Des-D, and the structure-activity relationship was discussed by in vitro anti-HIV activity.

Synthesis
We obtained 2,4,6-trihydroxy benzaldehyde (compound 1) in high yield via the Vilsmeier-Haack reaction with phloroglucinol dihydrate as the starting material to reduce costs [13].Then, we chose different catalysts, reagents, temperatures, and other conditions to optimize each step of the reported procedure.However, due to the extremely low content of Des-D, i.e., 0.04 ‱, in the plant [10], the synthesis of Des-D exhibited great potential and low cost, which could help to obtain enough products for subsequent biological activity studies.Nakagawa-Goto and Lee reported the total synthesis of Des-D first, showing a short route without the use of any protecting groups (Figure 2) [11].
Drugs Drug Candidates 2024, 3, FOR PEER REVIEW 2 of Phyllanthaceae family in China, which was found to have significant inhibitory activity against HIV.However, due to the extremely low content of Des-D, i.e., 0.04 ‱, in the plant [10], the synthesis of Des-D exhibited great potential and low cost, which could help to obtain enough products for subsequent biological activity studies.Nakagawa-Goto and Lee reported the total synthesis of Des-D first, showing a short route without the use of any protecting groups (Figure 2) [11].However, the high cost of this route could make the product uneconomical.Additionally, the instability of the reagent NaBH3CN and the relatively harsh reaction conditions could lead to poor efficiency and a low yield for the synthesis of Des-D.Due to the complex by-products and difficult purification process, the total yield was only 4.4% for the six steps, which posed difficulties for their massive synthesis [12].
Therefore, in this study, the synthesis of Des-D was optimized, and the total yield was further increased to 11.9% by using cheap starting materials, convenient reaction reagents, and a simplified separation and purification process.Meanwhile, 12 analogues were obtained by structural modification of Des-D, and the structure-activity relationship was discussed by in vitro anti-HIV activity.

Synthesis
We obtained 2,4,6-trihydroxy benzaldehyde (compound 1) in high yield via the Vilsmeier-Haack reaction with phloroglucinol dihydrate as the starting material to reduce costs [13].Then, we chose different catalysts, reagents, temperatures, and other conditions to optimize each step of the reported procedure.However, the high cost of this route could make the product uneconomical.Additionally, the instability of the reagent NaBH 3 CN and the relatively harsh reaction conditions could lead to poor efficiency and a low yield for the synthesis of Des-D.Due to the complex by-products and difficult purification process, the total yield was only 4.4% for the six steps, which posed difficulties for their massive synthesis [12].
Therefore, in this study, the synthesis of Des-D was optimized, and the total yield was further increased to 11.9% by using cheap starting materials, convenient reaction reagents, and a simplified separation and purification process.Meanwhile, 12 analogues were obtained by structural modification of Des-D, and the structure-activity relationship was discussed by in vitro anti-HIV activity.

Synthesis
We obtained 2,4,6-trihydroxy benzaldehyde (compound 1) in high yield via the Vilsmeier-Haack reaction with phloroglucinol dihydrate as the starting material to reduce costs [13].Then, we chose different catalysts, reagents, temperatures, and other conditions to optimize each step of the reported procedure.
Compound 1 was obtained by dissolving phloroglucinol dihydrate in ethyl acetate (EtOAc) and N,N-dimethylformamide (DMF) and then adding the appropriate amount of phosphorus oxychloride (POCl 3 ) via the Vilsmeier-Haack reaction for two hours, and the product could be recrystallized by water.
Then, compound 1 was dissolved in EtOAc via the slow dropwise addition of concentrated hydrochloric acid under nitrogen condition and ice bath condition, and then the reaction mixture was stirred overnight to obtain compound 2 in a yield of 86.4% after adding the reducing agent, zinc [14].Compound 3 and the by-product deacetylation product 4 (2,4,6trihydroxy-3-methyl-5-acetylacetophenone; this by-product could be used for the synthesis of analogues of Des-D) were obtained via the Friedel-Crafts acylation reaction from compound 2 in the presence of acetic acid (AcOH), Ac 2 O, and BF 3 •Et 2 O [15].Compound 5 was obtained by treating compound 3 with excess (Diazomethyl)trimethylsilane (TMSCHN 2 ) and reacting at a low temperature for 7 h.Formylation of 5 with Dichloromethyl methyl ether (Cl 2 CHOCH 3 ) in the presence of TiCl 4 gave compounds 6 and 7, as shown in Figure 3.This reaction should be carried out at −40 • C before moving to room temperature.Then, each of the rotated isomers was obtained, and both structures were verified through NMR, in which the shifts of the phenolic hydroxyl hydrogen protons of 6 are 15.02 ppm and 14.09 ppm, while those of 7 are 14.03 ppm and 12.56 ppm.The results showed that the main isomer, 6, was more stable than the minor isomer, 7, and more easily separated with a high yield [16].
Drugs Drug Candidates 2024, 3, FOR PEER REVIEW 3 Compound 1 was obtained by dissolving phloroglucinol dihydrate in ethyl acetate (EtOAc) and N,N-dimethylformamide (DMF) and then adding the appropriate amount of phosphorus oxychloride (POCl3) via the Vilsmeier-Haack reaction for two hours, and the product could be recrystallized by water.
Then, compound 1 was dissolved in EtOAc via the slow dropwise addition of concentrated hydrochloric acid under nitrogen condition and ice bath condition, and then the reaction mixture was stirred overnight to obtain compound 2 in a yield of 86.4% after adding the reducing agent, zinc [14].Compound 3 and the by-product deacetylation product 4 (2,4,6-trihydroxy-3-methyl-5-acetylacetophenone; this by-product could be used for the synthesis of analogues of Des-D) were obtained via the Friedel-Crafts acylation reaction from compound 2 in the presence of acetic acid (AcOH), Ac2O, and BF3•Et2O [15].Compound 5 was obtained by treating compound 3 with excess (Diazomethyl)trimethylsilane (TMSCHN2) and reacting at a low temperature for 7 h.Formylation of 5 with Dichloromethyl methyl ether (Cl2CHOCH3) in the presence of TiCl4 gave compounds 6 and 7, as shown in Figure 3.This reaction should be carried out at −40 °C before moving to room temperature.Then, each of the rotated isomers was obtained, and both structures were verified through NMR, in which the shifts of the phenolic hydroxyl hydrogen protons of 6 are 15.02 ppm and 14.09 ppm, while those of 7 are 14.03 ppm and 12.56 ppm.The results showed that the main isomer, 6, was more stable than the minor isomer, 7, and more easily separated with a high yield [16].Next, monoacylated product 8 and diacylated product 9 (3-methyl−4-methoxy-5formyl-2,6-benzyloxy-acetophenone) were obtained after the addition of BzCl to the mixture of activated 4Å-type molecular sieves and compounds 6 and 7 under a nitrogen atmosphere (Table 1).Subsequently, we tried to optimize the conditions for a high yield and regioselectivity.The excess BzCl (2 equiv) could lead to the obtainment of more 9 (Entry 1), while the equimolar BzCl (1 equiv.)did not obtain the corresponding 8 (Entry 2).The half of BzCl in Entry 2 was used for 9 and less than one-third for 8, which indicated that the low equivalent BzCl did not have a significant enough promoting effect on the generation of 8.The data also showed that the higher temperature of the reaction could lead to the high yield (Entries 1 and 3; Entries 2 and 4).In addition, the change in the reaction system (Entries 3 and 5) could not increase the yield of 8 or 9.The reason might be that the low temperature leads to the low yield, while the high temperature leads to the trend of compound 9′s production.Compound 8 was identified by 1 H NMR and 13 C NMR as an Next, monoacylated product 8 and diacylated product 9 (3-methyl−4-methoxy-5formyl-2,6-benzyloxy-acetophenone) were obtained after the addition of BzCl to the mixture of activated 4Å-type molecular sieves and compounds 6 and 7 under a nitrogen atmosphere (Table 1).Subsequently, we tried to optimize the conditions for a high yield and regioselectivity.The excess BzCl (2 equiv) could lead to the obtainment of more 9 (Entry 1), while the equimolar BzCl (1 equiv.)did not obtain the corresponding 8 (Entry 2).The half of BzCl in Entry 2 was used for 9 and less than one-third for 8, which indicated that the low equivalent BzCl did not have a significant enough promoting effect on the generation of 8.The data also showed that the higher temperature of the reaction could lead to the high yield (Entries 1 and 3; Entries 2 and 4).In addition, the change in the reaction system (Entries 3 and 5) could not increase the yield of 8 or 9.The reason might be that the low temperature leads to the low yield, while the high temperature leads to the trend of compound 9 ′ s production.Compound 8 was identified by 1 H NMR and 13 C NMR as an inseparable isomer mixture, which may be caused by the interaction of aldehyde, hydroxyl, and acetyl groups on the benzene ring (similar to 6 and 7).Compound 9 was obtained by recrystallization, using methanol.inseparable isomer mixture, which may be caused by the interaction of aldehyde, hydroxyl, and acetyl groups on the benzene ring (similar to 6 and 7).Compound 9 was obtained by recrystallization, using methanol.Compound 8 was used as raw material with pyridine (Py), DMAP, and KOH for the Baker-Venkataraman rearrangement.However, the experiment failed due to the difficulty in separation and purification.Then, we optimized the conditions according to similar reports [12,17], which used 8 and 9 in dry dimethyl sulfoxide (DMSO) reacted with potassium tert-butoxide (t-BuOK) as the base (Figure 4) [18].There was no obvious difference in the yield of Des-D from 8 or 9, so we chose the crude residue of 8 and 9 via the benzoylation of 6 and 7 to simplify operations and increase productivity.Des-D obtained from our works was confirmed by NMR as a mixture of enol and diketone structures coexisting, and the molar ratio of enol to diketone was about 2:1 at about 30 °C.The proportion of diketone structures would gradually increase as the temperature increased.The total yield of the entire synthetic route (raw material compound 1) was 11.9%.

Analogues
Using 2,6-dihydroxy acetophenone as a raw material and 4-chlorobenzene chloride as an acylating agent, monoacylated product 10 and diacylated product 12 were obtained.Subsequently, compounds 10 and 12 were reacted from the reaction system of DMSO and t-BuOK.After, recrystallization in methanol was used to obtain derivatives 11 and 13, respectively; the reaction process is shown in Figure 5.The yield of 13 showed that the method might be a potential procedure for the synthesis of flavones, and diacylated intermediates without hydrogen bonding next to hydroxyl groups could not yield the desired products instead of flavones.Since the low yield of the rearrangement step of 2,6-dihydroxy acetophenone as the raw material was insufficient for further modification studies as a substrate, we tried to use compound 2 for the synthesis.Compound 8 was used as raw material with pyridine (Py), DMAP, and KOH for the Baker-Venkataraman rearrangement.However, the experiment failed due to the difficulty in separation and purification.Then, we optimized the conditions according to similar reports [12,17], which used 8 and 9 in dry dimethyl sulfoxide (DMSO) reacted with potassium tert-butoxide (t-BuOK) as the base (Figure 4) [18].There was no obvious difference in the yield of Des-D from 8 or 9, so we chose the crude residue of 8 and 9 via the benzoylation of 6 and 7 to simplify operations and increase productivity.Des-D obtained from our works was confirmed by NMR as a mixture of enol and diketone structures coexisting, and the molar ratio of enol to diketone was about 2:1 at about 30 • C. The proportion of diketone structures would gradually increase as the temperature increased.The total yield of the entire synthetic route (raw material compound 1) was 11.9%.
inseparable isomer mixture, which may be caused by the interaction of aldehyde, hydroxyl, and acetyl groups on the benzene ring (similar to 6 and 7).Compound 9 was obtained by recrystallization, using methanol.The yield was less than 10%; b no products were determined.
Compound 8 was used as raw material with pyridine (Py), DMAP, and KOH for the Baker-Venkataraman rearrangement.However, the experiment failed due to the difficulty in separation and purification.Then, we optimized the conditions according to similar reports [12,17], which used 8 and 9 in dry dimethyl sulfoxide (DMSO) reacted with potassium tert-butoxide (t-BuOK) as the base (Figure 4) [18].There was no obvious difference in the yield of Des-D from 8 or 9, so we chose the crude residue of 8 and 9 via the benzoylation of 6 and 7 to simplify operations and increase productivity.Des-D obtained from our works was confirmed by NMR as a mixture of enol and diketone structures coexisting, and the molar ratio of enol to diketone was about 2:1 at about 30 °C.The proportion of diketone structures would gradually increase as the temperature increased.The total yield of the entire synthetic route (raw material compound 1) was 11.9%.

Analogues
Using 2,6-dihydroxy acetophenone as a raw material and 4-chlorobenzene chloride as an acylating agent, monoacylated product 10 and diacylated product 12 were obtained.Subsequently, compounds 10 and 12 were reacted from the reaction system of DMSO and t-BuOK.After, recrystallization in methanol was used to obtain derivatives 11 and 13, respectively; the reaction process is shown in Figure 5.The yield of 13 showed that the method might be a potential procedure for the synthesis of flavones, and diacylated intermediates without hydrogen bonding next to hydroxyl groups could not yield the desired products instead of flavones.Since the low yield of the rearrangement step of 2,6-dihydroxy acetophenone as the raw material was insufficient for further modification studies as a substrate, we tried to use compound 2 for the synthesis.

Analogues
Using 2,6-dihydroxy acetophenone as a raw material and 4-chlorobenzene chloride as an acylating agent, monoacylated product 10 and diacylated product 12 were obtained.Subsequently, compounds 10 and 12 were reacted from the reaction system of DMSO and t-BuOK.After, recrystallization in methanol was used to obtain derivatives 11 and 13, respectively; the reaction process is shown in Figure 5.The yield of 13 showed that the method might be a potential procedure for the synthesis of flavones, and diacylated intermediates without hydrogen bonding next to hydroxyl groups could not yield the desired products instead of flavones.Since the low yield of the rearrangement step of 2,6-dihydroxy acetophenone as the raw material was insufficient for further modification studies as a substrate, we tried to use compound 2 for the synthesis.The diacetylation product 4 was obtained via the acetylation of compound 2, which could increase the yield by the additional Ac2O.And then the benzoylation products 14, 15, and 16 were obtained in the presence of CH2Cl2 and Et3N via the one-pot reaction from 2. Then, 14 could react with NaOH in the presence of DMSO to give 17 via the Baker-Venkataraman rearrangement, and the structure was confirmed as shown in Figure 6 below.
. Moreover, the yield for compound 17 was only 37.5%, and the benzoylation of 4 caused 3 isomers, which made the yield low and difficult to separate and purify.Therefore, we screened another intermediate for total synthesis.The low yields of 8, 11, and 17 indicated that a hydroxyl group next to the acetyl group might reduce the efficiency of rearrangement reactions.
Based on the known active fragments of methoxy at the C-4 position, compound 3 was first treated with an excess of TMSCHN2 at room temperature.The main product, 18 (3-methyl-2-hydroxy-4,6-dimethoxy-acetophenone), was obtained after stirring for 24 h, which was found to be efficiently purified by recrystallization in methanol instead of column chromatography.Then, compound 19 (3-methyl-2-benzyloxy-4,6-dimethoxy-acetophenone) was obtained after introducing the benzyloxy group to compound 18.Afterward, compound 20 (tautomer) was obtained in 93.0%yield via Baker-Venkataraman rearrangement.The structure and procedure are shown in Figure 7; compound 18 was available as an important intermediate for the synthesis of other Des-D analogues on B-ring modification.The diacetylation product 4 was obtained via the acetylation of compound 2, which could increase the yield by the additional Ac2O.And then the benzoylation products 14, 15, and 16 were obtained in the presence of CH2Cl2 and Et3N via the one-pot reaction from 2. Then, 14 could react with NaOH in the presence of DMSO to give 17 via the Baker-Venkataraman rearrangement, and the structure was confirmed as shown in Figure 6 below.
. Moreover, the yield for compound 17 was only 37.5%, and the benzoylation of 4 caused 3 isomers, which made the yield low and difficult to separate and purify.Therefore, we screened another intermediate for total synthesis.The low yields of 8, 11, and 17 indicated that a hydroxyl group next to the acetyl group might reduce the efficiency of rearrangement reactions.
Based on the known active fragments of methoxy at the C-4 position, compound 3 was first treated with an excess of TMSCHN2 at room temperature.The main product, 18 (3-methyl-2-hydroxy-4,6-dimethoxy-acetophenone), was obtained after stirring for 24 h, which was found to be efficiently purified by recrystallization in methanol instead of column chromatography.Then, compound 19 (3-methyl-2-benzyloxy-4,6-dimethoxy-acetophenone) was obtained after introducing the benzyloxy group to compound 18.Afterward, compound 20 (tautomer) was obtained in 93.0%yield via Baker-Venkataraman rearrangement.The structure and procedure are shown in Figure 7; compound 18 was available as an important intermediate for the synthesis of other Des-D analogues on B-ring modification.Moreover, the yield for compound 17 was only 37.5%, and the benzoylation of 4 caused 3 isomers, which made the yield low and difficult to separate and purify.Therefore, we screened another intermediate for total synthesis.The low yields of 8, 11, and 17 indicated that a hydroxyl group next to the acetyl group might reduce the efficiency of rearrangement reactions.
Based on the known active fragments of methoxy at the C-4 position, compound 3 was first treated with an excess of TMSCHN 2 at room temperature.The main product, 18 (3-methyl-2-hydroxy-4,6-dimethoxy-acetophenone), was obtained after stirring for 24 h, which was found to be efficiently purified by recrystallization in methanol instead of column chromatography.Then, compound 19 (3-methyl-2-benzyloxy-4,6-dimethoxyacetophenone) was obtained after introducing the benzyloxy group to compound 18.Afterward, compound 20 (tautomer) was obtained in 93.0%yield via Baker-Venkataraman rearrangement.The structure and procedure are shown in Figure 7; compound 18 was available as an important intermediate for the synthesis of other Des-D analogues on B-ring modification.According to the successful procedure of analogue 20, the B ring was modified using different acylating agents to introduce halogenated benzene or alkylbenzene.A series of acylated products, 21, 23, 25, 27, 29, 31, 33, and 35, were obtained via the Baker-Venkataraman rearrangement, in which the corresponding products, 22, 24, 26, 28, 30, 32, 34, and 36, were all reciprocal isomers; see Figure 8 and Table 2.

Biological Activity
Subsequently, the HIV-1 integrase inhibitory activities of Des-D and its analogues were studied.As shown in Table 3, the positive control was Raltegravir (HIV integrase inhibitor), with the lowest IC50 value of 0.08 ± 0.04 μM.The lead compound, Des-D, showed the highest anti-HIV activity with a IC50 value of 13.6 ± 1.75 μM.However, the IC50 values of its derivatives, 17 and 11, were 101.3 ± 3.80 μM and 161.0 ± 3.27 μM, respectively, showing low HIV activity.And compounds 22, 24, 26, 28, 30, and 32 showed no inhibitory activity against HIV-1.

Biological Activity
Subsequently, the HIV-1 integrase inhibitory activities of Des-D and its analogues were studied.As shown in Table 3, the positive control was Raltegravir (HIV integrase inhibitor), with the lowest IC 50 value of 0.08 ± 0.04 µM.The lead compound, Des-D, showed the highest anti-HIV activity with a IC 50 value of 13.6 ± 1.75 µM.However, the IC 50 values of its derivatives, 17 and 11, were 101.3 ± 3.80 µM and 161.0 ± 3.27 µM, respectively, showing low HIV activity.And compounds 22, 24, 26, 28, 30, and 32 showed no inhibitory activity against HIV-1.

Molecular Docking
Finally, the binding mechanism of compounds Des-D and 17 was studied using computer-simulated molecular docking.The docking data are shown in Figures 9 and 10

Molecular Docking
Finally, the binding mechanism of compounds Des-D and 17 was studied using computer-simulated molecular docking.The docking data are shown in Figures 9 and 10

Molecular Docking
Finally, the binding mechanism of compounds Des-D and 17 was studied using computer-simulated molecular docking.The docking data are shown in Figures 9 and 10

General
Reagents were analytically or chemically purified and did not require further purification unless otherwise specified.All anhydrous solvents were dried and redistilled before being used in the usual manner.Thin-layer chromatography (TLC) was performed on pre-coated E. Merck silica gel 60 F254 plates (Kenneworth, NJ, USA).Flash column chromatography was performed on silica gel (300-400 mesh). 1 H NMR and 13 C NMR spectra were performed on a Bruker DPX 400 NMR transmission spectrometer (Saarbrucken, Germany) at 400 MHz, using tetramethylsilane as an internal standard, and chemical shifts were recorded as d-values.Mass spectral data were obtained using Bruker Apex IV RTMS, using ESI conditions.The synthesis procedures and spectral data of some compounds were reported [11].Compound 5 (631.1 mg, 3.2 mmol) was dissolved in 5 mL of dry dichloromethane, and then TiCl 4 (16 mL, 16 mmol, dissolved in 16 mL of dry CH 2 Cl 2 and Cl 2 CHOCH 3 (2.7 mL, 30.4 mmol) was added at −40 • C.After sufficient dissolution, the reaction device was transferred to a room-temperature environment and stirred overnight.The next day, the reaction was quenched by slowly adding an appropriate amount of ice water dropwise to the reaction solution at 0 • C, and the reaction was stopped after stirring for one hour.After adding dichloromethane and distilled water to both phases and extracting three times, the organic phase was collected and washed once with NaCl (aq) and desiccated with anhydrous Na 2 SO 4 .Compounds 6 and 7 were purified via column chromatography (eluent, EtOAc/PE = 1/12 to 1/8) after vacuum concentration (513.5 mg, 71.2% yield, white solid).TLC: R f = 0.3 (EtOAc/PE = 1/10).Compound 6: 1 H NMR (400 MHz, CDCl 3 ) δ 2.07 (s, 3H), 2.74 (s, 3H), 3.89 (s, 3H), 9.98 (s, 1H), 14.09 (s, 1H), 15.02 (s, 1H); 13

Biological Activity
The synthesized Des-D and 10 analogs were evaluated for anti-HIV-1 activity, using the method of HTRF.Recombinant HIV-1 integrase (HIV-1 integrase, referred to as HIV-IN) expressed in bacteria was selected as the model for evaluating the anti-HIV-1 integrase activity of the derivatives synthesized herein.

Experimental Methods (1) Protein expression and purification
The recombinant HIV-1 integrase protein expressed in bacteria must be purified [18,19].Briefly, the pellet was resuspended in A {25 mM Tris-HCI (pH 7.4), 1 M NaCl, 7.5 mM CHAPS}, and 25 mM imidazole protease inhibitor tablets.After sonication, the lysate was centrifuged at 45,000× g for 30 min.The supernatant was loaded into 5 mL of HisTrap FF and washed.The integrase was eluted with Buffer A containing 200 mM imidazole.Protein samples were concentrated and injected into a 5 mL Hitrap heparin column, and bound proteins were eluted in a linear gradient with 0.25 M~1 M NaCl in 25 mM Tris-HCl (pH 7.4)−7.5 mM CHAPS.The IN-containing fraction was pooled and dialyzed in buffer {25 mM HEPES (pH 7.6), 1 M NaCl 7.5 mM CHAPS, 0.1 mM EDTA, 1 mM DTT, and 10% glycerol}.The protein concentration was determined spectrophotometrically, frozen rapidly in liquid nitrogen, and stored at −80 • C.
(2) HTRF-based integrase activity assay Experiments were performed using an HTRF-based method [20,21].Wild-type integrase (final concentration 250 nM) was preincubated with serial dilutions of the compounds for 15 min at room temperature.Raltegravir was used as a positive control.Then, 12.5 nM Cy-5-labeled donor DNA and 5 nM biotinylated target DNA were added and incubated for 120 min at 37 • C. Europium-streptavidin was then added to the plates.After incubating the plates for 16 h at room temperature, the HTRF signal was recorded using a Perkin Elmer EnSpire multimode plate reader.Raw counts at 665 and 620 nm were collected, and the signal was expressed as a ratio of (cps at 665 nm/cps at 620 nm) × 1000.

Molecular Docking
The binding of compounds Des-D and 17 to HIV-IN [22] was examined dynamically via molecular docking simulations.
The protein 3D structure of HIV-IN was downloaded from the Protein Data Bank database (Protein Data Bank code: 3OYA).Des-D and compound 17 were first preprocessed for hydrogen bonding, using Mastero2020V22 software.Then, the HIV-IN protein was pre-processed for ligand compound extraction and dehydrogenation, and the format was converted to a pdbqt file.The structural formula files of Des-D and 17 after pretreatment were opened in Autodock4.2software and converted into pdbqt files, while the proteinligand compound files were opened to determine the active region of the HIV-IN protein with the active region set to x = 90.86,y = 50.504,and z = 114.826.Finally, AutoDock and Vina 4.2 software were used to perform molecular docking of Des-D and 17 with HIV-IN proteins, and the results were analyzed using PyMol molecular graphics system2.4software.

Conclusions
In this paper, the total synthesis of the natural product Des-D was optimized and completed with a yield of 11.9% compared with the work of Nakagawa-Goto and Lee (4.4%) [11].Then, Des-D and 12 analogues were designed and synthesized, and the HIV-IN inhibitory activity indicated that the natural product, Des-D, exhibited the most potent anti-HIV-IN activity, with an IC 50 value of 13.6 µM, while compounds 17 and 11 had low HIV-IN inhibition activity, with IC 50 values of 101.3 µM and 161.0 µM, respectively.The result of the computer-simulated molecular docking showed that the phenolic hydroxyl groups of Des-D and 17 formed salt bridges with the Mg 2+ -binding regions of A396 and A397, and the two aromatic benzene rings formed π-π stacks with D16 and D17, which

Figure 4 .
Figure 4.The synthesis of Des-D.

Figure 4 .
Figure 4.The synthesis of Des-D.

Figure 4 .
Figure 4.The synthesis of Des-D.

Figure 5 .
Figure 5. Synthesis of analogues 11 and 13.The diacetylation product 4 was obtained via the acetylation of compound 2, which could increase the yield by the additional Ac 2 O.And then the benzoylation products 14, 15, and 16 were obtained in the presence of CH 2 Cl 2 and Et 3 N via the one-pot reaction from 2. Then, 14 could react with NaOH in the presence of DMSO to give 17 via the Baker-Venkataraman rearrangement, and the structure was confirmed as shown in Figure6below.
. The phenolic hydroxyl groups of Des-D and 17 form salt bridges, binding regions of A396 and A397, and the two aromatic benzene rings interact with HIV-IN by forming π-π stacks with D16 and D17.The binding free energy of Des-D and HIV-IN is −10.4 kcal/mol, and the binding free energy of 17 and HIV-IN had a binding free energy of −9.6 kcal/mol.Drugs Drug Candidates 2024, 3, FOR PEER REVIEW 7 . The phenolic hydroxyl groups of Des-D and 17 form salt bridges, binding regions of A396 and A397, and the two aromatic benzene rings interact with HIV-IN by forming π-π stacks with D16 and D17.The binding free energy of Des-D and HIV-IN is −10.4 kcal/mol, and the binding free energy of 17 and HIV-IN had a binding free energy of −9.6 kcal/mol.

Figure 10 .
Figure 10.Docking of 17 with HIV-1 integrase protein molecule.Through the molecular docking of compounds Des-D and 17 with HIV-IN, the results show that phenolic hydroxyl groups and two aromatic benzene rings of Des-D and 17 are active functional groups that bind to HIV-IV.Because hydroxyl groups can bind to the core domain of HIV-IN, they cannot be protected.At the same time, the binding free energy of Des-D and HIV-IN is lower than that of 17 and HIV-IN, showing that Des-D is
. The phenolic hydroxyl groups of Des-D and 17 form salt bridges, binding regions of A396 and A397, and the two aromatic benzene rings interact with HIV-IN by forming π-π stacks with D16 and D17.The binding free energy of Des-D and HIV-IN is −10.4 kcal/mol, and the binding free energy of 17 and HIV-IN had a binding free energy of −9.6 kcal/mol.

Figure 10 .
Figure 10.Docking of 17 with HIV-1 integrase protein molecule.Through the molecular docking of compounds Des-D and 17 with HIV-IN, the results show that phenolic hydroxyl groups and two aromatic benzene rings of Des-D and 17 are active functional groups that bind to HIV-IV.Because hydroxyl groups can bind to the core domain of HIV-IN, they cannot be protected.At the same time, the binding free energy of Des-D and HIV-IN is lower than that of 17 and HIV-IN, showing that Des-D is

Figure 10 .
Figure 10.Docking of 17 with HIV-1 integrase protein molecule.Through the molecular docking of compounds Des-D and 17 with HIV-IN, the results show that phenolic hydroxyl groups and two aromatic benzene rings of Des-D and 17 are active functional groups that bind to HIV-IV.Because hydroxyl groups can bind to the core domain of HIV-IN, they cannot be protected.At the same time, the binding free energy of Des-D and HIV-IN is lower than that of 17 and HIV-IN, showing that Des-D is easier to bind to HIV-IN than 17, and the results can be mutually corroborated with the activity research test.

( 3 )
CalculationThe inhibition rate of integrase was calculated according to the following equation: Inhibition rate(%) = (1 − OD value of experimental group − Blank group OD Control group OD − Blank group OD ) × 100%

Table 1 .
Screening of benzoylation reaction conditions.

Table 1 .
Screening of benzoylation reaction conditions.
a The yield was less than 10%; b no products were determined.

Entry Solvent BzCl (eq) Alkali/Catalyst Temperature Yield (8) Yield (9)
The yield was less than 10%; b no products were determined. a

Table 1 .
Screening of benzoylation reaction conditions.

Table 2 .
Structure of B-ring analogues.

Table 2 .
Structure of B-ring analogues.

Table 2 .
Structure of B-ring analogues.

Table 3 .
Activity data of target compounds for HIV-1 integrase inhibition.

Table 3 .
Activity data of target compounds for HIV-1 integrase inhibition.

Table 3 .
Activity data of target compounds for HIV-1 integrase inhibition.