Systematics and Phylogenetic Placement of Panicum L. Species within the Melinidinae Based on Morphological, Anatomical, and Molecular Data (Poaceae, Panicoideae, Paniceae)

Generic boundaries of the African species Panicum deustum Thunb., Panicum trichocladum Hack. ex K. Schum., and Panicum vollesenii Renvoize are analyzed and compared with related genera of the tribe Paniceae and the subtribe Melinidinae. Based on morphological (vegetative and reproductive characters including habit, ligules, inflorescence, spikelets, and ornamentation of the upper anthecium), anatomical (transverse section of leaves), and molecular data (three chloroplast markers), a new genus is proposed for P. deustum, while P. trichocladum and P. vollesenii are transferred to the genus Megathyrsus (Pilg.) B.K. Simon & S.W.L. Jacobs. The phylogenetic position of both taxa within the Melinidinae and their morphological affinities with other genera of the subtribe are also discussed. Additional studies on the Melinidinae will clarify the systematic position of the genera that are still in a doubtful position within the subtribe, such as Eriochloa and Urochloa.


Introduction
Within the grass family Poaceae, the Paniceae, with the ages of the stem and the crown estimated to be in the Eocene and Oligocene, respectively, has an Afrotropical ancestral distribution and is dispersed and diversified pantropically since the late Oligocene [1]. Members of the Paniceae share a bi-flowered spikelet, their lower floret is male or neuter, and the upper floret is typically perfect and usually indurated; additionally, the taxa of this tribe mostly have a basic chromosome number of x = 9. This tribe includes five subtribes. Among them, the subtribe Melinidinae [2] has a total of 14 genera and three "incertae sedis" species of Panicum grex Deustum [3]. Of these, Megathyrsus (Pilg.) B.K. Simon & S.W.L. Jacobs is a genus with species in Africa and Eurasia [4], and M. maximus (Jacq.) B.K. Simon & S.W.L. Jacobs is an introduced species all over the world. Tricholaena Schrad., with two species, also has a distribution in Africa and Asia, and Moorochloa Veldkamp includes three species in Africa and Eurasia. Finally, Melinis P. Beauv., with nearly 23 species [4], has the conspicuously introduced species, M. minutiflora P. Beauv. and M. repens (Willd) Zizka, all over the world. Thuarea Pers. grows in Madagascar, Eurasia, and Australasia, while the monotypic Eccoptocarpha Launert and Yvesia A. Camus are present in Africa, the latter being restricted to Madagascar. Three genera are restricted to America: Scutachne Hitchc. & Chase is a monotypic genus endemic of Cuba, Rupichloa Salariato & Morrone comprehends two species that are restricted to Brazil, and Chaetium Nees has three species distributed from Mexico and the Caribbean to northern Brazil. Finally, two genera are cosmopolitan: Eriochloa Kunth, with approximately 33 species, and Urochloa P. Beauv., with more than 100 species, are in need of a taxonomic revision.
Early diversification of Melinidinae was placed through the early Miocene in the Afrotropics [1], while its monophyly has been recovered in several contributions

Phylogenetic Reconstruction
The general features and descriptive statistics of the DNA datasets used in the phylogenetic analyses are presented in Table S1 [available in supplementary material here]. Plastid ndhF region has the most variable dataset with 297 (13.94%) phylogenetically informative sites, followed by trnL-F and rpl16 which have 127 (10.83%) and 115 (9.68%) phylogenetically informative characters, respectively. The ILD test of the tree cpDNA combined does not indicate incongruence between partitions (ILD: P = 0.73). The strict consensus tree from MP, the 50% majority-rule consensus tree from BI, and the ML tree recovered using similar topologies show the same strongly supported clades; therefore, only the BI tree of the combined three-region DNA dataset is presented here (Figure 1). All aligned data matrices and trees of separate and combined datasets from the three methods of analysis are available at Repositorio Institucional CONICET Digital under the following link: http://hdl.handle.net/11336/17622, accessed on 23 December 2022.
We were able to include three accessions of P. deustum, which have identical or nearly identical sequences and are placed together by the three analyses. In the case of P. trichocladum, mutations in the sequences lead the two accessions to distinct placements, but both are included in Megathyrsus. We were able to amplify only a single voucher specimen of P. vollesenii that corresponds to the type collection of the name (Figure 1; Table S2 available in Supplementary Material here). The topology of the three-region DNA dataset groups all the Melinidinae accessions analyzed in a strongly supported clade (Bayesian posterior probability (BPP) 1/ML bootstrap (MLB) 98/parsimony bootstrap (PB) 100), with P. deustum, P. trichocladum and P. vollesenii included in it ( Figure 1). The backbone of the tree is not fully resolved, but all combined analyses placed P. deustum, P. trichocladum, and P. vollesenii into two clades, as detailed next. Figure 1. A 50% majority-rule consensus tree from the Bayesian inference analysis of the total combined dataset (ndhF + rpl16 + trnL-F). Bootstrap supports from parsimony are listed above the branches and bootstrap supports from maximum likelihood/posterior probabilities with Bayesian inference are listed below the branches. Nodes with "-" have bootstrap supports ˂ 50%. Clades denoted by letters are discussed in the text. Figure 1. A 50% majority-rule consensus tree from the Bayesian inference analysis of the total combined dataset (ndhF + rpl16 + trnL-F). Bootstrap supports from parsimony are listed above the branches and bootstrap supports from maximum likelihood/posterior probabilities with Bayesian inference are listed below the branches. Nodes with "-" have bootstrap supports < 50%. Clades denoted by letters are discussed in the text. The topology of the three-region DNA dataset groups all the Melinidinae accessions analyzed in a strongly supported clade (Bayesian posterior probability (BPP) 1/ML bootstrap (MLB) 98/parsimony bootstrap (PB) 100), with P. deustum, P. trichocladum and P. vollesenii included in it ( Figure 1). The backbone of the tree is not fully resolved, but all combined analyses placed P. deustum, P. trichocladum, and P. vollesenii into two clades, as detailed next.
The Transverse section (Figure 2A,B): The leaf outline is flat to very open V, with 90-160 µm in width and with ribs and furrows that are scarcely distinctive. The semicircular median keel developed with adaxial colorless parenchyma and some primary vascular bundles, generally three, and several second-and third-order vascular bundles; all bundles are in an abaxial position and are indistinguishable structurally from the lateral vascular bundles. The mesophyll with chlorenchyma cells conspicuously radiates in a single layer of cells around the vascular bundles; there are usually 2-3 mesophyll cells between contiguous vascular bundles. The vascular bundles have an outer parenchymatous sheath with globose cells and specialized chloroplasts in a centrifugal position, complete or interrupted by abaxial girds of sclerenchyma in the first-order vascular bundles. There are generally parenchymatous bundle cells of second-and third-order vascular bundles that are similar in size to first-order vascular bundles, with 9-12 parenchyma sheath cells surrounding first-order vascular bundles and 6-8 cells surrounding second-and third-order vascular bundles. The inner mestome sheath has cell walls that are thickened and has no chloroplasts in all vascular bundles. Very small strands of adaxial and/or abaxial sclerenchyma are associated with minor vascular bundles. Bulliform cells form well-defined and regular groups of 2-6 cells between consecutive vascular bundles or above third-order vascular bundles, occupying approximately 1 ⁄4 of the leaf thickness. The leaf outline is flat to very open V, with 70-120 µm in width and with ribs and furrows that are scarcely distinctive. The semicircular median keel developed with scarce adaxial colorless parenchyma and one first-order vascular bundle in P. vollesenii or abundant adaxial colorless parenchyma and three first-order vascular bundles in P. trichocladum. In both species, there are some minor-order vascular bundles. All bundles are in an abaxial position, indistinguishable structurally from the lateral vascular bundles. The mesophyll with chlorenchyma cells radiates or conspicuously radiates in a single layer of cells around the vascular bundles; there are generally 1(-2) mesophyll cells between contiguous vascular bundles. The vascular bundles have outer parenchymatous sheath with globose cells and specialized chloroplasts in a centrifugal position, complete or abaxially interrupted by the girds of sclerenchyma in the first-order vascular bundles. There are parenchymatous bundle cells of minor vascular bundles that are bigger than first-order vascular bundles, with 8-10 parenchyma sheath cells surrounding the first-order vascular bundles and commonly 4(-6) cells surrounding the minor-order vascular bundles; these cells are arranged in a cross and, with the adaxial and abaxial cells, are somewhat winged. The inner mestome sheath has cell walls that are thickened and has no chloroplasts in all vascular bundles; in some cases, there is no differentiation between second-and third-order vascular bundles. Very small strands of adaxial and/or abaxial sclerenchyma are associated with minor vascular bundles. Bulliform cells form welldefined and regular groups of 2-4 cells between consecutive vascular bundles, occupying approximately 1 ⁄4 of the leaf thickness; there are adaxial and abaxial macrohairs with cushion based in P. trichocladum. ts 2023, 12, x FOR PEER REVIEW 5 of surrounding the first-order vascular bundles and commonly 4(-6) cells surrounding t minor-order vascular bundles; these cells are arranged in a cross and, with the adaxial a abaxial cells, are somewhat winged. The inner mestome sheath has cell walls that a thickened and has no chloroplasts in all vascular bundles; in some cases, there is no d ferentiation between second-and third-order vascular bundles. Very small strands adaxial and/or abaxial sclerenchyma are associated with minor vascular bundles. Bu form cells form well-defined and regular groups of 2-4 cells between consecutive vascu bundles, occupying approximately ¼ of the leaf thickness; there are adaxial and abax macrohairs with cushion based in P. trichocladum.

Ornamentation of the Upper Anthecia
The upper lemma of P. deustum shows a smooth surface without longitudinal or transverse ridges ( Figure 3A-D), with simple papillae of 2-4 µm associated with the transverse anticlinal wall zone (one on each wall). Alternatively, in P. trichocladum and P. vollesenii, the ornamentation pattern in the upper lemma is characterized by prominent transverse pustules ( Figure 3E-H), while longitudinal pustules are absent or very slight. Generally, a single papilla of 5-8 µm is associated with the transverse anticlinal wall.

Discussion
The particular configuration of the outer bundle sheath associated with the thirdorder vascular bundles in P. trichocladum and P. vollesenii is a diagnostic character that confirms the transfer of both species to the genus Megathyrsus. Similar to all Melinidinae, both species of Panicum, Megathyrus infestus, and M. maximus are C4 of the PCK subtype [13][14][15][16] but differ by the presence of usually four cells that surround the minor vascular bundles; therefore, Kranz parenchyma cells are arranged in a cross, frequently with the adaxial and abaxial cells being somewhat expanded and the vascular tissue looking square in transection. Other species that potentially could be included in this group, at least regarding the foliar anatomy, are Panicum chusqueoides Hack. (Brachiaria chusqueoides (Hack.) W.D. Clayton and Brachiaria grossa Stapf ( [18]; Aliscioni, pers. obs.).
On the contrary, P. deustum lacks these anatomical characters. In this species, there are usually 6-8 Kranz parenchyma cells that surround minor-order vascular bundles, i.e., adjusted to a more classic pattern of the C4-PCK subtype. The other genera that integrate the sister clade of P. deustum all have a smooth upper lemma and also share a similar foliar anatomy. Previously, [18] mentioned these anatomical similarities, particularly for Moorochloa eruciformis, M. malacodes (named as a species of Brachiaria in his work) and Tricholaena; a similar foliar anatomy is present in Leucophrys mesocoma [11] and Melinis minutiflora [24], the latter with bulliforms associated with colorless mesophyll cells [25].
Panicum deustum is characterized by its lanceolate, cordate to subcordate leaves and inflorescence terminal, which is lax and open, and is usually covered with clavellate hairs. The spikelets are long ellipsoid, with the lower glume being 5-nerved; the upper glume, and lower lemma are subequal, being 5-7-nerved. The lower palea is developed, the lower flower staminate, and the upper anthecium is smooth, shiny, and indurate, with macrohairs at the top of the upper lemma ( Figure 3A-D). This species has a basic chromosome number of x = 9.
Within the Melinidinae, the genus Chaetium¸ including three American species, is defined by its spiciform inflorescences, with spikelets that are dorsiventrally compressed

Discussion
The particular configuration of the outer bundle sheath associated with the third-order vascular bundles in P. trichocladum and P. vollesenii is a diagnostic character that confirms the transfer of both species to the genus Megathyrsus. Similar to all Melinidinae, both species of Panicum, Megathyrus infestus, and M. maximus are C 4 of the PCK subtype [13][14][15][16] but differ by the presence of usually four cells that surround the minor vascular bundles; therefore, Kranz parenchyma cells are arranged in a cross, frequently with the adaxial and abaxial cells being somewhat expanded and the vascular tissue looking square in transection. Other species that potentially could be included in this group, at least regarding the foliar anatomy, are Panicum chusqueoides Hack. (Brachiaria chusqueoides (Hack.) W.D. Clayton and Brachiaria grossa Stapf ( [18]; Aliscioni, pers. obs.).
On the contrary, P. deustum lacks these anatomical characters. In this species, there are usually 6-8 Kranz parenchyma cells that surround minor-order vascular bundles, i.e., adjusted to a more classic pattern of the C 4 -PCK subtype. The other genera that integrate the sister clade of P. deustum all have a smooth upper lemma and also share a similar foliar anatomy. Previously, [18] mentioned these anatomical similarities, particularly for Moorochloa eruciformis, M. malacodes (named as a species of Brachiaria in his work) and Tricholaena; a similar foliar anatomy is present in Leucophrys mesocoma [11] and Melinis minutiflora [24], the latter with bulliforms associated with colorless mesophyll cells [25].
Panicum deustum is characterized by its lanceolate, cordate to subcordate leaves and inflorescence terminal, which is lax and open, and is usually covered with clavellate hairs. The spikelets are long ellipsoid, with the lower glume being 5-nerved; the upper glume, and lower lemma are subequal, being 5-7-nerved. The lower palea is developed, the lower flower staminate, and the upper anthecium is smooth, shiny, and indurate, with macrohairs at the top of the upper lemma ( Figure 3A-D). This species has a basic chromosome number of x = 9.
Within the Melinidinae, the genus Chaetium¸including three American species, is defined by its spiciform inflorescences, with spikelets that are dorsiventrally compressed and with a callus at the base; the glumes are awned, the lower one is long and lanceolate to setaceous, and the upper anthecium papillose all over its surface. The genus Eccoptocarpha, with one African species, includes an annual plant. It has racemose inflorescences and few flowers; the spikelets are dorsiventrally compressed and adaxial; the lower glume is 3 ⁄4 of the length of the spikelet; the upper glume and lower lemma have transverse veinlets; and the upper anthecium is stipitate, being shorter than the upper glume and the lower lemma, smooth, shiny, glabrous and indurate. The polyphyletic genus Eriochloa, cosmopolitan and with nearly 35 species [4] in need of a revision, comprehends species with racemose to open and lax inflorescences. The spikelets are dorsiventrally compressed; the lower glume is reduced to a globose callus at its base; and the upper anthecium is longitudinally striate and has verrucose papillae, is mucronate or aristulate, indurate, and pilose toward the apex or glabrous. The genus Leucophrys, with two African species, is defined by its racemose inflorescences; the spikelets are appressed and adaxial, and dorsiventrally compressed, the lower glume is nearly as long as the upper glume, being 1-5-nerved; the upper glume and lower lemma are pilose; and the upper anthecium is smooth, shiny, glabrous, and indurate. Megathyrsus is an African genus, with ca. three species, related to Urochloa, and is characterized by its open and radiated inflorescences; the spikelets are dorsiventrally compressed and not stipitate; the lower glume is 1 / 3 to 1 ⁄4 of the length of the spikelet, being (1-)3-nerved; and the upper anthecium is transversely rugose, crustaceous, mucronate, and glabrous. The genus Melinis, with approximately 30 species distributed in Africa and Asia, is introduced in America and includes species with lax and open inflorescences; the spikelets are laterally compressed and articulated below the upper anthecium; the lower glume is less than 1 ⁄5 of the length of the spikelet and is nerveless; and the upper anthecium is smooth, shiny, muticous, glabrous, herbaceous to cartilagineous. The genus Moorochloa, with three species distributed in Africa and Asia, is introduced elsewhere and has spikelets that are arranged in unilateral racemes, dorsiventrally compressed, and articulated below the upper anthecium; the lower glume is less than 1 ⁄5 of the length of the spikelet, being 1nerved; and the upper anthecium is smooth, shiny, muticous, glabrous, and cartilagineous. Rupichloa is a genus restricted to Brazil with two species, which is defined by its open and lax inflorescences; the spikelets are dorsally compressed and stipitate; the lower glume is 1 ⁄2 to 3 ⁄4 of the length of the spikelet, being 5-7-nerved; and the upper anthecium is longitudinally striate, crustaceous, covered with verrucose papillae, crestate, and has flattened macrohairs toward the apex. Scutachne, which is monotypic and has one species restricted to Cuba, is distinguished by having spikelets that are dorsiventrally compressed and stipitate, the lower glume is 1 ⁄2 of the length of the spikelet and is 5-7-nerved, and the upper anthecium is longitudinally striate, papillose, with the apex crested and pilose. Thuarea, with two species from Madagascar, Australia, and Asia, includes andromonoic plants, has racemose inflorescences and is entirely deciduous at maturity; the rachis is winged and ending in a naked point; the spikelets are adaxial; the lower glume is absent or obscure and nerveless; and the upper anthecium is smooth, indurate, muticous and pilose at the apex. The genus Tricholaena, with four species from Africa, Madagascar, and Eurasia, has open and lax inflorescences, with spikelets that are laterally compressed; the lower glume is less than 1 ⁄5 of the length of the spikelet, being 0-1-nerved; and the upper anthecium is smooth, shiny, glabrous, and muticous. Urochloa, a cosmopolitan genus with nearly 100 species, differs by its radiated or racemose inflorescences, with spikelets that are dorsiventrally compressed and are stipitate or not; the lower glume is 1 ⁄6 to the same length of the spikelet, being (0-)3-7(9-11)-nerved; and the upper anthecium is transversely rugose or longitudinally striate, with simple or verrucose papillae, and is indurate, mucronate to crestate or aristulate. Finally, Yvesia, a monotypic genus endemic to Madagascar, includes annual plants with racemose and digitate inflorescences and few flowers; the spikelets are dorsiventrally compressed, falling entire at maturity; the lower glume is absent or vestigial and is nerveless; and the upper anthecium is smooth, indurate, glabrous, and mucronate.

Distribution and ecology. Africa (Ethiopia to South Africa), Temperate Asia, and South America (introduced).
Observations. This species has a chromosome number of 2n = 36 [26]. The specimen Holst 8816, from K, is designated as a lectotype of P. pubivaginatum K. Schum., among the two syntypes originally cited in this species, since it is a full specimen and agrees with the protologue.
Distribution and ecology. Africa, present from Ethiopia and Sudan to Democratic Republic of the Congo, Kenya, Tanzania, Uganda, Zambia, Zimbabwe, Malawi, and Mozambique; it is introduced in Tropical Asia and South America. It grows in bush or forest shade, and on stony or sandy soils.
Observations. This species has a chromosome number of 16 [27]. Panicum trichocladum was described on the basis of two syntypes, Meyer 140 and Volkens 69, both from Tanzania. Of these, Meyer 140 from B (B 10 0715462), which is a full specimen in agreement with the protologue, is designated here as a lectotype of the species.
Panicum simbense was described on the basis of two syntypes, Stuhlmann 28, and Holst 378. Both specimens are not extant at B, presumably lost during WW2. Therefore, a lectotype of Holst 378, which agrees with the protologue, is designated from US, a fragment of the original material at B.
Observation. This species is morphologically related to P. trichocladum, the latter differing by its reduced, nerveless, and obtuse-to-truncate lower glume [28].

Taxon Sampling
The DNA data matrix used here consisted of a total of 125 accessions, of which 111 are ingroup corresponding to the Melinidinae taxa. Previously published chloroplast DNA (cpDNA) ndhF, rpl16, and trnL-F matrices [11], excluding the outgroup, were completed with new sequences downloaded from GenBank (42, 5, and 4, respectively), plus the new accessions of P. deustum, P. trichocladum and P. vollesenii that were sequenced for this study [ Table S2, available in Supplementary Material here]. In addition, 14 species belonging to six closely related genera were selected as the outgroup, based on [11,12,29]: Aakia J.R. Grande, Anthaenantiopsis Mez ex Pilg., Cenchrus L., Panicum, Paspalum L., and Setaria P. Beauv. The information about the vouchers and accession numbers of the new sequences obtained for this study and those downloaded from GenBank is presented in Table S2.

DNA Amplification and Sequencing
Total genomic DNA was extracted from herbarium specimens using modified CTAB protocols from [30]. Some DNA extractions were conducted using the DNeasy Plant Mini Kit (Qiagen, Hilden, Germany), following the manufacturer's recommendations. Each species was amplified from a single voucher specimen, but a second voucher was also included for some taxa. The three cpDNA regions were amplified using polymerase chain reaction (PCR) and sequenced for each taxon. The complete ndhF gene, coding NADH dehydrogenase subunit F, was amplified with a battery of primers in different combinations in four overlapping fragments using the primer pairs specified by [7,31]: 5F-536R, 536F-972R, 972F-1666R, and 1666F-3R; the rpl16 region, corresponding to the intron and partial sequences of the gene encoding ribosomal protein L16 [32][33][34], was amplified in two fragments using primers F71 [35] and R1661 [32], combined with the internal ones F584 and R584 [36]; finally, the trnL intron and trnL-F spacer were amplified by PCR in two fragments using the primers C, D, E, and F of [37].
PCR reactions were performed in a 25 µL final volume with 50-100 ng of template DNA, 5 µL of Green Promega GoTaq ® buffer (5 u/µL), 0.5 µL of MgCl 2 (25 mM), 1.25 µL of dNTP (10 mM), 1 µL of each primer (10 pM), and 0.3 µL of Taq polymerase (5 u/µL) provided by Promega (Madison, Wisconsin, U.S.A.). For the species that failed this protocol, variations in MgCl 2 (0.5-1 µL) and total DNA dilutions (1:5, 1:10 and 1:50) were used. The reactions were carried out using the following parameters: one cycle of 95 • C for 2 min, 39 cycles of 95 • C for 30 s, 48 • C for 30 s, and 72 • C for 1.5 min, and a final extension cycle of 72 • C for 10 min. The PCR products were run out on a 1% TBE agarose gel stained with SYBR Safe DNA gel stain (Invitrogen) and visualized in a blue-light transilluminator. The PCR products were purified, and automated sequencing was performed by Macrogen, Inc. (Seoul, South Korea). Forward and reverse strands were sequenced for all fragments, with a minimum overlap of 80%.

Phylogenetic Analyses
The sequences were edited and assembled in MEGA v. 7.0 [38]. To check the accuracy, all sequences were translated to aminoacids and the point substitutions were checked against the original sequencing trace file. Alignments were generated using Clustal X v. 2 [39] under the default settings and, when necessary, manually improved. The phylogenetic reconstruction was based on parsimony (MP) [40], maximum likelihood (ML) [41,42], and Bayesian inference (BI) [43] methods. In all analyses, gaps were considered as missing data. The best-fitting nucleotide substitution models for the three regions were determined by using the Akaike information criterion (AIC), as implemented in jModeltest 2.1.1 [44]: TVM+I+G (ndhF) and TPM1uf+I+G (rpl16 and trnL-F).
For the three approaches, each cpDNA region matrix was analyzed separately before the analysis of the combined datasets. Separate and combined parsimony analyses were conducted in TNT ver. 1.1 [45]. All characters were equally weighted and treated as unordered. A heuristic search was conducted with 1000 random addition sequences, tree bisection and reconnection (TBR) branch swapping, saving up to 15 trees per replicate. The resulting trees were then submitted to a second-round search of TBR branch swapping to completion. Nonparametric bootstrap support (BS) [46] was estimated using 10,000 pseudoreplicates, and the same parameters were used in our MP analyses.
The ML analyses were performed in RAxML-HPC2 on XSEDE (v. 8.2.12) [47] through the Cyberinfrastructure for Phylogenetic Research (CIPRES) Portal v. 3.3 [48]. For these analyses, we used non-parametric bootstrap (BS) analysis and searched for the best-scoring ML tree in a single run [49]. To this end, we performed 1000 rapid bootstrap inferences with a subsequent search of the maximum likelihood tree, using the GTRGAMMA nucleotide substitution model [49], individual per-site substitution rates (-c), and default setting of likelihood acceptance (-e), 25 and 0.1, respectively. Individual and combined BI analyses were conducted in MrBayes v. 3.2.7a [50] through the CIPRES Portal [48] with nst = 6 and rates= invgamma, unlinking models across loci for combined analyses. The datasets were analyzed in two parallel runs of four simultaneous Markov chains for 10 million generations, sampling every 1000 generations and using the default parameters. Convergence and effective sample size (ESS) of the runs were assessed by checking the parameters in Tracer v.1.7 [51]. After discarding the initial 2500 trees of each run as burn-in (25%), the remaining trees (15,002) were used to generate a 50% majority-rule consensus tree. The cutoff for strong support in the Bayesian analyses was 0.95 (roughly equal to p < 0.05), and posterior probabilities and values below 0.8 were considered not supported.

Anatomical and Morphological Analyses
The anatomical and taxonomic studies were based on bibliographical research including recent studies (e.g., [52,53], among others) and original descriptions, as well as analyses of herbarium specimens housed in B, BR, C, FT, G, K, MO, NY, P, UBT, US, and W [54]. We examined types in person and the images are available online at the JSTOR Global Pants website (http://plants.jstor.org, accessed on 10 October 2022) and/or at the websites of aforementioned herbaria. The protologues of all taxa were checked. Unless otherwise stated, the specimen designated as the lectotype was that which matches the protologue, corresponds to the current usage of the plant name, and is in the best preservation condition, according to the modern rules of the International Code of Nomenclature (ICN) [55]. For each name, the place of valid publication is given followed by the holotype or lectotype and an explanation of the nomenclatural decisions made.
The spikelets and upper anthecia were viewed using a Philips XL 30 TMP at an accelerating voltage of 80 kV in the scanning electron microscope. The foliar anatomy was analyzed in the second leaf below the inflorescence. The histological preparations were made from the herbarium materials that were rehydrated by submerging them in water with a commercial detergent and heating them in an oven at 50 • C for 24 h, followed by fixing them in FAA. The cross-sectional leaf anatomy was determined from the hand-sectioned leaf blades, after clarifying with 50% sodium hypochlorite, being stained with Safranin and Alcian Blue [56], and being mounted in glycerin jelly. The observations and measurements were made using a Wild M20 optical light microscope and photomicrographs were taken using Axio Vs40 V 4.8.2.0 (Carl Zeiss). The terminology for the anatomical characters and descriptions were based on [57,58].

Conclusions
Our study allowed us to exclude three species of the Melinidineae from the genus Panicum on the basis of morphological and molecular characters, establishing a new genus in the subtribe and transferring the remaining two species to the genus Megathyrsus. In addition, we present here a summary of the main features of the genera of the subtribe, including a key to distinguishing the genera of the Melinidineae.
Supplementary Materials: The following supporting information can be downloaded at https:// www.mdpi.com/article/10.3390/plants12020399/s1, Table S1: Descriptive statistics for each separate data partition and combined matrices used in the parsimony analyses. Table S2: Taxa, voucher information, and GenBank accession numbers for ndhF, rpl16, and trnL-F, respectively.