Regulation of cytoskeletal structure in human mammary carcinoma cells MCF-7 by culture substrata

Three-dimensional cellular structures formed by MCF-7 human mammary carcinoma cells within collagen gels were isolated with collagenase and cultivated on plastic substratum to examine whether the cytoskeleton specific for cells forming cellular structures (S-type) changes to that specific for cells grown as monolayers (M-type). The cytoskeleton isolated as 0.05% Triton-insoluble fraction from the cellular structures after culture for 1 day on plastic was exclusively S-type. However, both types of cytoskeletons were observed in the cellular structures cultivated for 7 days on plastic as well as in the cells grown as monolayers for 2 days after dissociation of the cellular structures with trypsin. By use of an antibody raised against a 65-kD polypeptide that was specific for the M-type cytoskeleton, the presence of the polypeptide was found to be restricted to the cells grown out as monolayers from the edge of the cellular structures. In the cells grown for 2 days as monolayers, a mixture of cells both having and lacking the polypeptide was observed. After a 7-day culture of the dissociated cells as monolayers on plastic, however, most of the cells had M-type cytoskeletons. The present results show that the apparent change in the cytoskeleton of MCF-7 cells from S-type to M-type does not occur in cells involved in the three-dimensional cellular structures even in the absence of collagen gels, but that it occurs in cells which are grown as monolayers for at least 7 days on plastic substratum.     

Regulation of growth and differentiation of a rat hepatoma cell line by the synergistic interactions of hormones and collagenous substrata

Serum-free, hormonally defined media have been developed for optimal growth of a rat hepatoma cell line. The cells' hormonal requirements for growth are dramatically altered both qualitatively and quantitatively by whether they were plated onto tissue culture plastic or collagenous substrata. On collagenous substrata, the cells required insulin, glucagon, growth hormone, prolactin, and linoleic acid (bound to BSA), and zinc, copper, and selenium. For growth on tissue culture plastic, the cells required the above factors at higher concentrations plus several additional factors: transferrin, hydrocortisone, and triiodothyronine. To ascertain the relative influence of hormones versus substratum on the growth and differentiation of rat hepatoma cells, various parameters of growth and of liver-specific and housekeeping functions were compared in cells grown in serum-free, hormonally supplemented, or serum-supplemented medium and on either tissue culture plastic or type I collagen gels. The substratum was found to be the primary determinant of attachment and survival of the cells. Even in serum-free media, the cells showed attachment and survival efficiencies of 40-50% at low seeding densities and even higher efficiencies at high seeding densities when the cells were plated onto collagenous substrata. However, optimal attachment and survival efficiencies of the cells on collagenous substrata still required either serum or hormonal supplements. On tissue culture plastic, there was no survival of the cells at any seeding density without either serum or hormonal supplements added to the medium. A defined medium designed for cells plated on tissue culture plastic, containing increased levels of hormones plus additional factors over those in the defined medium designed for cells on collagenous substrata, was found to permit attachment and survival of the cells plated into serum-free medium and onto tissue culture plastic. Growth of the cells was influenced by both substrata and hormones. When plated onto collagen gel substrata as compared with tissue culture plastic, the cells required fewer hormones and growth factors in the serum-free, hormone-supplemented media to achieve optimal growth rates. Growth rates of the cells at low and high seeding densities were equivalent in the hormonally and serum-supplemented media as long as comparisons were made on the same substratum and the hormonally supplemented medium used was the one designed for that substratum. For a given medium, either serum or hormonally supplemented, the saturation densities were highest for tissue culture plastic as compared with collagen gels.(ABSTRACT TRUNCATED AT 400 WORDS)     

Laboratory culture of the Oriental lancelet Branchiostoma belcheri

To overcome difficulties in getting research materials of cephalochordate lancelets, which has severely hampered experimental studies of this animal, we have attempted to establish a culture system in the laboratory. Adult animals collected from the wild were maintained in 2.5-L plastic containers filled with natural seawater without sand substratum. They were fed daily with unicellular algae. About 25% of the animals collected in 2003, 2004, and 2005 developed gonads in our culture system. Some of the sexually mature animals collected in the breeding seasons in 2005 and 2006 spawned spontaneously in the plastic containers of this system. Broods obtained in 2005 were maintained longer than a year in a glass tank without sand substratum. The progeny born in the laboratory showed great individual variation in growth but metamorphosed normally, and some of them started to develop gonads around 10 months after fertilization. Our mass culture methods for both adults and their progeny made daily observation possible and allowed the constant spawning of animals collected from the wild, at least in the summer season. Our culture method saves labor in maintenance and is easily set up without any specific demands except for running seawater, though still required to better survival rate and spawning control. Lancelet populations maintained in the laboratory can promote studies on these animals across disciplines and especially contribute to elucidation of the evolutionary history of chordates.     

Effect of inoculation on the biodegradation of wathered Prudhoe Bay crude oil

Summary Enrichment cultures from oil-contaminated beach material from Prince William Sound, Alaska, generated both a mixed bacterial community of indigenous, oil-degrading marine microorganisms and a pure culture oil-degrader, strain EI2V. The mixed and axenic cultures were used in comparative shake flask studies of inoculation on biodegradation of Prudhoe Bay crude oil. Within 12 h following inoculation of homogenized, oiled beach material with the mixed culture, total CO₂ production was increased 2-fold relative to a noninoculated control. Moreover, measurements of phenanthrene degradation (as determined by the release of¹⁴CO₂ from [9-¹⁴C]phenanthrene) showed a 2-or 3-fold greater degradation when inoculated with either strain EI2V or with the mixed culture, respectively. However, as medium was replaced by a simulated tidal cycle, the observed stimulation of CO₂ production decreased, and the addition of strain EI2V had no greater effect on total CO₂ production than the addition of inorganic nutrients alone. Chemical analysis of oil recovered after 7 days incubation also suggested that, while these cultures are capable of efficient biodegradation of Prudhoe Bay crude in liquid culture, inoculation of beach material with high numbers of these microorganisms had little effect on the rate and extent of biodegradation of weathered crude oil. Overall, the sustained stimulatory effect was no greater than that observed with the addition of inorganic nutrients alone.     

Planktonic versus biofilm catabolic communities: importance of the biofilm for species selection and pesticide degradation

Chloropropham-degrading cultures were obtained from sludge and soil samples by using two different enrichment techniques: (i) planktonic enrichments in shaken liquid medium and (ii) biofilm enrichments on two types of solid matrixes (plastic chips and gravel). Denaturing gradient gel electrophoresis fingerprinting showed that planktonic and biofilm cultures had a different community composition depending on the presence and type of added solid matrix during enrichment. This was reflected in the unique chloropropham-degrading species that could be isolated from the different cultures. Planktonic and biofilm cultures also differed in chloropropham-degrading activity. With biofilm cultures, slower chloropropham removal was observed, but with less build-up of the toxic intermediate 3-chloroaniline. Disruption of the biofilm architecture resulted in degradation characteristics shifting toward those of the free suspensions, indicating the importance of a well-established biofilm structure for good performance. These results show that biofilm-mediated enrichment techniques can be used to select for pollutant-degrading microorganisms that like to proliferate in a biofilm and that cannot be isolated using conventional shaken-liquid procedures. Furthermore, the influence of the biofilm architecture on the pesticide degradation characteristics suggests that for bioaugmentation the use of biofilm catabolic communities might be a proficient alternative to using planktonic freely suspended cultures.     

Serum and substratum-dependent coupled loss of differentiated and tumorigenic phenotypes in B16-conv melanoma cells

Clonal B16 mouse melanoma conv cells are tumorigenic spindle-shaped cells (S-type cells) exhibiting tyrosinase activity and melanosomes under usual culture conditions. When the cells passaged on glass substratum were plated for colony formation on plastic substratum in Eagle's minimum essential medium (MEM) with 10% calf bovine serum, most of them converted to fibroblastlike cells (F-type cells) with the coupled loss of differentiated and tumorigenic phenotypes. However, they continued to be S-type cells provided that they were plated on glass substratum. The conversion from S- to F-type cell was not induced with high frequency even on plastic substratum when the concentration of calf serum in the medium was low (1-2%). These results indicate that both plastic substratum and serum factor are requisites for converting the phenotypic expression of the conv cells. Partial characterization of the serum factor indicates that it is adsorbable to plastic substratum, inactivated at 70 degrees C for 10 min, salted out at 40% of saturated ammonium sulfate; in addition the factor seems to act on cells within 1 day after plating.     

Serum-free primary culture of normal mouse mammary epithelial and stromal cells

Summary An in vitro serum-free culture system provides an important approach to the understanding of local hormonal regulation of mammary epithelial and fibroblast cells, avoiding the complexity of the in vivo environment and the influence of undefined serum factors. The substratum conditions and medium components have been examined for the basal growth of epithelial cells, fibroblasts, and combined epithelial and fibroblast cells in monolayer cultures. Epithelial cells and mixed cells exhibit good attachment and maintenance on a collagen-coated surface in a minimal medium supplemented with fetuin and insulin. In contrast, fibroblast-enriched cultures require a plastic substratum and a medium supplemented with insulin, fetuin, and hydrocortisone. In mixed cell culture, fibroblasts are maintained well in the minimal media which supports the maintenance of epithelial cells. These results indicate that the presence of epithelial cells in mixed cell cultures can influence fibroblast function. The media developed in the present study can be used in future studies of fibroblast and epithelial cell interactions with regard to hormone and growth factor regulation of their growth and differentiation.     

Cell to substratum adhesion-promoting activity released by normal and virus-transformed cells in culture

It is demonstrated here that cultured fibroblasts release into their medium a nondialyzable, protease-sensitive factor(s) capable of promoting the adhesion and spreading of virus-transformed rat fibroblasts on a plastic substratum. A relatively sensitive biological assay is described for quantitation of the adhesion-promoting factor (APF) activity in serum-free, conditioned medium harvested from the cultures. Evidence is presented which indicates that the primary mode of action of the APF is by binding to and modifying the properties of the substratum. Conditioned media harvested after 24 h of incubation in similarly populated cultures of normal fibroblasts of diverse animal species exhibited similar levels of APF activity. However, conditioned media obtained from Rous sarcoma virus (Prague strain)-transformed and avian sarcoma virus B77-transformed rat fibroblasts exhibited three- to sixfold lower levels of APF activity than media conditioned in parallel cultures of heterologous or homologous normal fibroblasts. Cultivation of B77 virus-transformed rat cells in the presence of dibutyryl cyclic AMP and theophylline led to as much as a sevenfold increase in the level of APF activity appearing in the culture medium, with a concomitant increase in the adhesiveness of the cells to the culture substratum. The results support the role of extracellular macromolecules in cell to substratum adhesion. It is postulated that the reduced adhesiveness of transformed cells to a substratum may be at least partially owing to a deficiency in the production and/or release of APF-like macromolecules.     

Possible requirement of collagen gel substratum for production of mucin-like glycoproteins by primary rabbit tracheal epithelial cells in culture

Summary Primary rabbit tracheal epithelial cells growing on either plastic surface or collagen gel produce high molecular weight glycoconjugates. Biochemical characterization of these materials show they are exclusively hyaluronic acid when cells are grown on plastic surface, but a mixture of hyaluronic acid and mucin-like glycoproteins when grown on collagen gel. This research suggests that the substratum plays an important role in the maintenance or differentiation or both of mucous cells in culture.     

Inhibition of byssal formation in Semimytilus algosus (Gould, 1850) by a film-forming bacterium isolated from biofouled substrata in northern Chile

Semimytilus algosus is a small mussel species that fouls artificial culture systems of the scallop Argopecten purpuratus (Lamarck, 1819) in the north of Chile. Since biofouling organisms are a serious problem in culture, competing with the scallops for food and oxygen, environmentally-friendly methods are required to mitigate the effects of this fouling in the culture systems. The present study reports the evaluation of the inhibitory effect of biofilms and extracellular products (EP) of the bacterium Alteromonas strain Ni1-LEM on the byssal formation of S. algosus juveniles. Laboratory bioassays were carried out to determine the reattachment, exploratory behaviour and/or byssal thread production of the mussel in plastic Petri dishes containing bacterial biofilms, different dilutions of EP, and EP incorporated in a test substratum. It was concluded from the results that culture supernatants of the Alteromonas tested had an inhibitory effect on reattachment by S. algosus.     

The effect of tenascin and embryonic basal lamina on the behavior and morphology of neural crest cells in vitro

We have investigated the morphology and migratory behavior of quail neural crest cells on isolated embryonic basal laminae or substrata coated with fibronectin or tenascin. Each of these substrata have been implicated in directing neural crest cell migration in situ. We also observed the altered behavior of cells in response to the addition of tenascin to the culture medium independent of its effect as a migratory substratum. On tenascin-coated substrata, the rate of neural crest cell migration from neural tube explants was significantly greater than on uncoated tissue culture plastic, on fibronectin-coated plastic, or on basal lamina isolated from embryonic chick retinae. Neural crest cells on tenascin were rounded and lacked lamellipodia, in contrast to the flattened cells seen on basal lamina and fibronectin-coated plastic. In contrast, when tenascin was added to the culture medium of neural crest cells migrating on isolated basal lamina, a significant reduction in the rate of cell migration was observed. To study the nature of this effect, we used human melanoma cells, which have a number of characteristics in common with quail neural crest cells though they would be expected to have a distinct family of integrin receptors. A dose-dependent reduction in the rate of translocation was observed when tenascin was added to the culture medium of the human melanoma cell line plated on isolated basal laminae, indicating that the inhibitory effect of tenascin bound to the quail neural crest surface is probably not solely the result of competitive inhibition by tenascin for the integrin receptor. Our results show that tenascin can be used as a migratory substratum by avian neural crest cells and that tenascin as a substratum can stimulate neural crest cell migration, probably by permitting rapid detachment. Tenascin in the medium, on the other hand, inhibits both the migration rates and spreading of motile cells on basal lamina because it binds only the cell surface and not the underlying basal lamina. Cell surface-bound tenascin may decrease cell-substratum interactions and thus weaken the tractional forces generated by migrating cells. This is in contrast to the action of fibronectin, which when added to the medium stimulates cell migration by binding both to neural crest cells and the basal lamina, thus providing a bridge between the motile cells and the substratum.     

Differential Effects of TGF-β1 on Hyaluronan Synthesis by Fetal and Adult Skin Fibroblasts: Implications for Cell Migration and Wound Healing

Fetal wound healing differs from its adult counterpart in that it is regenerative and occurs without scarring. The matrix macromolecule hyaluronan (HA) and various cytokines, including members of the TGF-β family, have been implicated in the control of scarring. We have previously reported that adult and fetal fibroblasts differ with respect to the effect of cell density on HA synthesis when cultured on plastic tissue culture dishes. Data regarding the effects of substratum and TGF-β1 on HA synthesis by these cells are presented in this communication. Our results indicate that HA synthesis by both fetal and adult fibroblasts is (a) up-regulated by culture on a collagen substratum and (b) differentially regulated by TGF-β1 in a manner which is dependent upon both substratum and cell density. TGF-β1 stimulated HA synthesis by confluent fetal fibroblasts growing on a plastic substratum, but inhibited HA synthesis on a collagen substratum; these data underscore the important role of the substratum in determining the precise effect of TGF-β1 on cell behavior. Related studies indicated that the migration of fetal and adult fibroblasts into the collagen substrata was modulated by TGF-β1 in a manner identical to its effect on HA synthesis. These observations are discussed in terms of the contribution of distinct fibroblast subpopulations to wound healing and the manner in which this is regulated by matrix and cytokines.     

Characteristics of the cultivation of epidermocytes on collagen substratum

Epidermocytes obtained from human split-thickness skin were cultured in hypocalcium medium (ion calcium content was 0.14 mM). The half bottoms of culture plastic dishes were coated with collagen film before bringing cells in these dishes. It was proved that epidermocytes attach more quickly to collagen, than to plastic substratum, incorporate H3-thymidine (at early periods of cultivation) with larger rate and form and monolayer more quickly, than on the plastic substratum.     

Mucin synthesis and secretion by cultured tracheal cells: effects of collagen gel substratum thickness

Summary We previously demonstrated that human tracheobronchial epithelial (TBE) cells synthesize mucin and form mucous granules in culture when they are maintained on a collagen gel (CG) substratum, but not on a plastic tissue culture surface or a thin collagen-coated surface (Wu et al., Am. J. Respir. Cell Mol. Biol., 3:467–478; 1990). This observation led us to examine the effects of CG thickness on cell growth and differentiation in primary human/monkey TBE cell cultures. Using the same CG preparation, culture dishes with different thicknesses of CG substratum were prepared. In general, equivalent degrees of cell attachment and proliferation were observed in all cultures maintained on a collagen gel, independent of the thicknesses of CG substratum. However, a greater degree of mucin synthesis and secretion by the cells was observed as the thickness of the CG substratum was increased. Cultures maintained on a thick collagen gel (1 mm) exhibited greater apical membrane complexity, more pseudostratification, and more mucous granules than did cultures maintained on a thin CG substratum. The optimal culture surface for airway mucous cell differentiation contains more than 1-mm thickness of collagen gel substratum.     

Properties and fate of plasma fibronectin bound to the tissue culture substratum

Plasma fibronectin (pFn) is a serum protein which, when adsorbed to a glass or plastic substratum, mediates the adhesion of fibroblasts in culture. We have studied some of the details of its adsorption and subsequent fate. By using ¹²⁵l-labeled pFn, we show that a substratum incubated with pFn adsorbs approximately 0.4 μg/cm² pFn (a monomolecular layer), and one incubated with medium containing serum adsorbs approximately 7 ng/cm² pFn (a 12-fold enrichment relative to a random selection of the soluble proteins). SDS-polyacrylamide gel electrophoresis (SDS-PAGE) suggests the bound serum proteins (eluted with SDS) are primarily BSA and β-globulins. The bound pFn adheres so tightly, though, that most resists elution, as assayed (1) with pFn radioiodinated before binding, (2) with pFn radioiodinated after binding, or (3) by the cell spreading activity of the bound pFn retained after SDS treatment. Under culture conditions, there is a continuous “turnover” of substratum-bound pFn: soluble pFn can bind to a serum-coated substratum, while bound pFn is gradually removed by incubation with serum proteins. The presence of fibroblasts increases the rate of this removal several-fold. By SDS-PAGE the material removed (as well as that eluted from the substratum with SDS after cell detachment) is intact pFn or large (possibly proteolytically generated) fragments. Thus, pFn binds preferentially to the tissue culture substratum, but can be removed subsequently by the combined action of cells and other serum proteins.     

Collagen metabolism and spicule formation in sea urchin micromeres

The role of collagen or collagen-like protein(s) in the in vitro formation of the sea urchin embryonic skeleton was investigated using isolated micromeres of Strongylocentrotus purpuratus. Micromeres were cultured in sea water containing 4% horse serum on tissue culture plastic or an extracellular matrix of type I collagen. The effect of proline analogs and an inhibitor of collagen hydroxylation on in vitro spicule formation in both culture systems was monitored. When micromeres are cultured in the presence of proline analogs l-azetidine-2-carboxylic acid and l-3,4-dehydroproline which disrupt collagen metabolism, spicule formation is significantly less inhibited on a collagen substratum than on plastic. Culturing micromeres on plastic in the presence of α,α′-dipyridyl, an inhibitor of collagen hydroxylation, resulted in almost complete inhibition of spicule formation. The inhibition by α,α′-dipyridyl can be overcome by culturing micromeres on collagen substratum. These results do not support the idea of collagen being the calcified organic matrix of the spicule. Rather, they suggest that micromeres synthesize a collagen-like extracellular matrix which is necessary for spicule formation. Inhibition of this activity by proline analogs or a collagen processing inhibitor can be overcome by providing the cells with a previously deposited extracellular matrix.     

Influence of organic nutrients and cocultures on the competitive behavior of 1,2-dichloroethane-degrading bacteria.

The effects of organic nutrients and cocultures on substrate removal by and competitive behavior of 1,2-dichloroethane-degrading bacteria were investigated. Xanthobacter autotrophicus GJ10 needed biotin for optimal growth on 1,2-dichloroethane. In continuous culture, dilution of biotin to a concentration below 0.2 nM resulted in washout. Growth could be restored by inoculation with the 2-chloroethanol utilizer Pseudomonas sp. strain GJ1, leading to a new steady state in which about 1% of the mixed culture consisted of cells of strain GJ1. This indicates that strain GJ1 excreted biotin or a precursor for its synthesis. Inoculation of the mixed culture with Ancylobacter aquaticus AD25 did not result in washout of strain GJ10, although strain AD25 has a 10-fold-lower Ks for growth on 1,2-dichloroethane. Strain AD25 did not become dominant because of the lack of vitamins, which are necessary for its optimal growth. The results indicate that medium composition and the presence of other species strongly influence the effect of substrate limitation on the composition of a bacterial population that degrades a xenobiotic compound in a continuous culture.     

Influence of collagen gel substratum on response to low-density lipoprotein by cultured human skin fibroblasts

The effect of low-density lipoprotein (LDL) on accumulation of glycosaminoglycans (GAG) was compared in cultures of human skin fibroblasts on a conventional plastic substratum and in a native type I collagen gel. The 24-h incorporation of [3H]glucosamine and Na2(35)SO4 into GAG secreted into the medium or associated with the substratum and cell surface (SCA) was measured in cells at subconfluent densities. When cells were grown on plastic, 13-25% of the labeled GAG was in the SCA pool. Cells cultured within a collagen gel matrix incorporated three times more [3H]glucosamine and up to five times more [35S]sulfate into this pool. The addition of LDL (300 micrograms protein/mL) to the medium increased the level of total GAG incorporation of [3H]glucosamine by 40-50% and of [35S]sulfate by 15-20% on both substrata. For cells on plastic the relative increase in the medium and SCA pool was similar, whereas for cells in collagen gel the response to LDL was twice as great in the SCA pool as in the medium. The distribution of GAG types was unaffected by LDL; hyaluronic acid remained the principal GAG in the media pools of both substrata, heparan sulfate remained the main SCA GAG in cultures on plastic, and dermatan sulfate remained the dominant GAG in the SCA pool of collagen gel cultures. LDL degradation was measured at intervals up to 48 h after the addition of 125I-labeled LDL. The rate of accumulation of degraded LDL products was lower in collagen gel cultures, but the final levels achieved were the same in the two substrata. Concentrations of total cell cholesterol were similar, although the increases in free cholesterol induced by LDL were 26% greater in cells within collagen gel than in those on plastic. We conclude that fibroblasts grown within a collagen gel, as compared with those on a plastic substratum, (i) accumulate more GAG that remain attached to the substratum and cell surface; (ii) respond to LDL with a similar degree of increase in GAG accumulation, but more of the increase is found in the substratum and cell surface compartment; and (iii) accumulate more intracellular free cholesterol in response to LDL.     

The nature of substrate-attached materials in human fibroblast cultures: localization of cell and fetal calf serum components.

Human fibroblasts have been used as an in vitro model to examine the morphology and origin of substrate-attached materials. In cultures of subconfluent cells, no ‘tracks’ or ‘pools’ of material could be detected on substrata by anodic oxide interferometry or electron microscopy. However, a continuous layer of densely staining material was present on Falcon plastic tissue culture dishes never exposed to cells or culture medium. Exposure of substrata to culture medium caused the adsorption of fetal calf serum (FCS) components onto the substratum within a few minutes. Although antigenic FCS components remained on the substrata for several days, they were seldom adsorbed to the cells. The hypothesis was formulated that adhesion was mediated by FCS components on the substrata, but not by cellular materials deposited extracellularly. Support for this hypothesis was obtained by studying serum-dependent differences in cell adhesion. Fibroblasts subcultured in the presence of FCS components were usually separated from the substratum by a distance of at least 30 Å. In the absence of FCS components, the cells were more closely adherent, in the range at which the near van der Walls forces were effective. Fibroblasts subcultured in the absence of serum components could be removed readily from the substratum, leaving lsfootprints’ of cell surface material behind. Although this material has been prepared similarly to ‘microexudates’ from other types of cultured cells, its relationship to those microexudates has not been determined.     

Megafaunal community structure of Andaman seamounts including the Back-arc Basin--a quantitative exploration from the Indian Ocean

Species rich benthic communities have been reported from some seamounts, predominantly from the Atlantic and Pacific Oceans, but the fauna and habitats on Indian Ocean seamounts are still poorly known. This study focuses on two seamounts, a submarine volcano (cratered seamount--CSM) and a non-volcano (SM2) in the Andaman Back-arc Basin (ABB), and the basin itself. The main purpose was to explore and generate regional biodiversity data from summit and flank (upper slope) of the Andaman seamounts for comparison with other seamounts worldwide. We also investigated how substratum types affect the megafaunal community structure along the ABB. Underwater video recordings from TeleVision guided Gripper (TVG) lowerings were used to describe the benthic community structure along the ABB and both seamounts. We found 13 varieties of substratum in the study area. The CSM has hard substratum, such as boulders and cobbles, whereas the SM2 was dominated by cobbles and fine sediment. The highest abundance of megabenthic communities was recorded on the flank of the CSM. Species richness and diversity were higher at the flank of the CSM than other are of ABB. Non-metric multi-dimensional scaling (nMDS) analysis of substratum types showed 50% similarity between the flanks of both seamounts, because both sites have a component of cobbles mixed with fine sediments in their substratum. Further, nMDS of faunal abundance revealed two groups, each restricted to one of the seamounts, suggesting faunal distinctness between them. The sessile fauna corals and poriferans showed a significant positive relation with cobbles and fine sediments substratum, while the mobile categories echinoderms and arthropods showed a significant positive relation with fine sediments only.