Chamberlainium capense Puckree-Padua, P.W. Gabrielson et Maneveldt, 2021

Puckree-Padua, Courtney A., Gabrielson, Paul W. & Maneveldt, Gavin W., 2021, DNA sequencing reveals three new species of Chamberlainium (Corallinales, Rhodophyta) from South Africa, all formerly passing under Spongites yendoi, Botanica Marina (Warsaw, Poland) 64 (1), pp. 19-40 : 22-25

publication ID

https://doi.org/ 10.1515/bot-2020-0074

DOI

https://doi.org/10.5281/zenodo.11191648

persistent identifier

https://treatment.plazi.org/id/039387E3-FF8C-FF9C-8838-062106C5FD28

treatment provided by

Felipe

scientific name

Chamberlainium capense Puckree-Padua, P.W. Gabrielson et Maneveldt
status

sp. nov.

Chamberlainium capense Puckree-Padua, P.W. Gabrielson et Maneveldt sp. nov.

( Figures 4 View Figures 4–6 , 7–11 View Figures 7–11 , 12–14 View Figures 12–14 , 15–18 View Figures 15–18 ; Tables 1, 2).

Holotype: L 3986119 , 09.x.2016, leg. G. W. Maneveldt, collection number 16/05, epilithic on primary bedrock in mid-intertidal, sand inundated rock pool.

Type locality: South Africa, Western Cape Province, Mouille Point (33°53.9440′ S, 18°24.5285′ E) GoogleMaps .

Etymology: ‘ capense ’ in reference to the species’ restricted distribution along the Cape Peninsula historically known as the ‘ Cape of Good Hope, South Africa’ (Caput Bonae Spei).

Description: Non-geniculate, thalli are moderately thick (up to 1000 µm), encrusting to mostly variably lumpy to slightly protuberant. Thalli are epilithic or epizoic and bright to dusky pink in well-lit conditions. Individual crusts do not appear to fuse together and are easily discernible. Thallus construction is monomerous with a single layer of epithallial cells. A central columella is present in tetrasporangial conceptacles that disintegrate to form a low mound with maturity. The pore opening in mature tetrasporangial conceptacles is occluded by a corona of filaments that projects above the opening. The psb A (851 bp) and rbc L (691–1387 bp) sequences are diagnostic.

Habitat: Thalli were epilithic on the primary bedrock and on large boulders in rock pools and on exposed platforms in the mid-intertidal zone, as well as epizoic on mollusc shells in the low intertidal zone.

Vegetative morphology and anatomy: Thalli were non-geniculate, moderately thick (up to 1000 μ m), encrusting (smooth) to mostly variably lumpy and slightly protuberant, with protuberances to 4 mm tall ( Figures 4 View Figures 4–6 and 7, 8 View Figures 7–11 ), and were firmly adherent, dusky pink to mauve (in well-lit conditions) to rosy or purple-pink (in dim light) when freshly collected ( Figure 4 View Figures 4–6 ). Individual crusts did not fuse together and were easily discernible ( Figures 7, 8 View Figures 7–11 ).

Thalli were dorsiventrally organized, monomerous and haustoria were absent. The medulla was thin and plumose (non-coaxial) ( Figures 9, 10 View Figures 7–11 ). Medullary filaments comprised rectangular to elongate cells, which gave rise to cortical filaments that comprised mainly square to rectangular cells ( Figure 10 View Figures 7–11 ). Contiguous medullary and cortical filaments were joined by cell fusions; secondary pit connections were absent ( Figure 10 View Figures 7–11 ). Subepithallial initials (intercalary meristematic cells) were square to rectangular ( Figure 11 View Figures 7–11 ). The epithallus was single layered with oval to rounded cells ( Figure 11 View Figures 7–11 ). Trichocytes were common at the thallus surface and occurred singularly (mostly) to paired ( Figure 11 View Figures 7–11 ). Trichocytes were always terminal and never intercalary in the cortex; buried trichocytes were not observed. Data on morphological and measured vegetative characters are summarized in Table 1.

Reproductive morphology and anatomy: Gametangial thalli appeared to be dioecious, although female plants were not observed.

Spermatangial (male) conceptacles were uniporate, low-domed and raised above surrounding thallus surface ( Figures 12–14 View Figures 12–14 ). Conceptacle chambers were transversely elliptical to flatten; conceptacle roof nearly twice as thick along pore canal ( Figures 13, 14 View Figures 12–14 ). Conceptacle roof formed from filaments peripheral to the fertile area ( Figure 12 View Figures 12–14 ). Throughout the early development, a protective layer of epithallial cells surrounded the conceptacle primordium ( Figure 12 View Figures 12–14 ). This protective layer was shed once the pore canal was near fully developed. The pore opening was occluded by a mucilage plug ( Figures 13, 14 View Figures 12–14 ). In mature conceptacles, terminal initials along pore canal were enlarged and papillate; they projected into the pore canal and were orientated more or less parallel to the conceptacle roof surface ( Figure 14 View Figures 12–14 ). Unbranched (simple) spermatangial systems were confined to mature conceptacle floor ( Figures 12–14 View Figures 12–14 ). Senescent male conceptacles appeared to be shed; no buried conceptacles were observed.

Tetrasporangial thalli were morphologically similar to spermatangial thalli. Conceptacles were uniporate, low domed and raised above the surrounding thallus surface ( Figures 15–17 View Figures 15–18 ). Conceptacle chambers were transversely elliptical to bean-shaped. Conceptacle roof was nearly twice as thick along the pore canal and was 5–7 cells thick, including an epithallial cell. Pore canal tapered towards the surface, formed an arch ( Figure 18 View Figures 15–18 ) and was lined by elongated papillate cells that projected into the canal and were orientated more or less parallel or nearly perpendicular to the conceptacle roof surface ( Figure 18 View Figures 15–18 ). The roof was formed from filaments peripheral to the fertile area ( Figure 15 View Figures 15–18 ) and terminal initials were more elongate than their inward derivatives. Throughout early development a protective layer of epithallial cells surrounded the conceptacle primordium ( Figure 15 View Figures 15–18 ). This protective layer was shed once pore canal was near fully developed; the pore opening was occluded by a corona of filaments that projected above the pore opening ( Figures 16, 18 View Figures 15–18 ). The corona appeared to form from filaments near the upper half of the roof, directly adjacent to the pore canal ( Figures 16, 18 View Figures 15–18 ). Throughout the development of the tetrasporangial conceptacle, a prominent columella of sterile filaments formed at the center of the conceptacle chamber ( Figure 15 View Figures 15–18 ), which extended into the pore canal ( Figure 16 View Figures 15–18 ); the central columella appeared weakly calcified as with maturity it disintegrated to form a low mound ( Figure 17 View Figures 15–18 ). The base of the pore canal was sunken into the chamber and terminal initials near the base pointed downward ( Figure 18 View Figures 15–18 ). Mature conceptacle floors were sunken 11– 17 cells (including the epithallial cell) below the surrounding thallus surface. Zonately divided tetrasporangia were arranged at the extreme periphery of the conceptacle chamber and were attached via a stalk cell ( Figures 16, 17 View Figures 15–18 ). Where the central columella had disintegrated or diminished, the tetrasporangia filled the chamber and appeared to be distributed across the chamber floor ( Figure 17 View Figures 15–18 ). Senescent tetrasporangial conceptacles appeare to be shed as no buried conceptacles were observed. Data on reproductive characters are summarized in Table 2.

Distribution: Confirmed by DNA sequences to have a restricted distribution (± 43 km distance) along the southwest coast, from Mouille Point to Slangkop (Western Cape Province) along the Cape Peninsula, South Africa.

G

Conservatoire et Jardin botaniques de la Ville de Genève

W

Naturhistorisches Museum Wien

A

Harvard University - Arnold Arboretum

L

Nationaal Herbarium Nederland, Leiden University branch

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