Changes in the midgut cells in the European cave spider, Meta menardi, during starvation in spring and autumn

Lipovšek, Saška; Leitinger, Gerd; Novak, Tone; Janžekovič, Franc; Gorgoń, Szymon; Kamińska, Karolina; Rost‐Roszkowska, Magdalena

doi:10.1007/s00418-017-1623-z

Cited by 29 publications

(48 citation statements)

References 47 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In this study, we focused on the ultrastructural changes in the midgut diverticle epithelial cells of M. menardi during a four-month winter starvation experiment. These findings enable the completion of the comparative study of responses to starvation in M. menardi in critical phases of the life cycle: the beginning and the end of the growth period 35 with abundant food and winter with scarce food (this study). Our experimental conditions mimic the natural starvation period of M. menardi which occurs if they fail to catch prey during wintertime.…”

Section: Discussionmentioning

confidence: 98%

“…We asked which are characteristic changes in the midgut diverticle epithelial cells, and which energy-supplying compounds M. menardi spend during overwintering. Finally, we compared findings in M. menardi starved during the growing period with relatively abundant prey 35 , and those starved during the wintertime with much more limited prey availability. This analysis of the whole-year response to starvation in M. menardi could eventually decover some specific features in supporting cells with energy and nutrients in the hypothetically stepwise adaptation to subterranen habitats.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Changes in the midgut diverticula epithelial cells of the European cave spider, Meta menardi, under controlled winter starvation

Lipovšek

Novak

Janžekovič

et al. 2018

Sci Rep

Self Cite

View full text Add to dashboard Cite

The European cave spider, Meta menardi, is among the most common troglophile species inhabiting the cave entrance zone in Europe, where prey is scarce in winter. Spiders feed only if prey is available; otherwise, they are subjected to long-term winter starvation. We carried out a four-month winter starvation of M. menardi under controlled conditions to analyze ultrastructural changes in the midgut diverticula epithelial cells at the beginning, in the middle and at the end of the starvation period. We used light microscopy, TEM and quantified reserve lipids and glycogen. The midgut diverticula epithelium consisted of secretory cells, digestive cells and adipocytes. During starvation, gradual vacuolization of some digestive cells, and some necrotic digestive cells and adipocytes appeared. Autophagic structures, autophagosomes, autolysosomes and residual bodies were found in all three cell types. Spherites and the energy-reserve compounds were gradually exploited, until in some spherites only the membrane remained. Comparison between spring, autumn and winter starvation reveals that, during the growth period, M. menardi accumulate reserve compounds in spherites and protein granules, and energy-supplying lipids and glycogen, like many epigean, overwintering arthropods. In M. menardi, otherwise active all over the year, this is an adaptive response to the potential absence of prey in winter.

show abstract

Section: Discussionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Changes in the midgut diverticula epithelial cells of the European cave spider, Meta menardi, under controlled winter starvation

Lipovšek

Novak

Janžekovič

et al. 2018

Sci Rep

Self Cite

View full text Add to dashboard Cite

show abstract

“…This process should be correlated to the diffusion of ions in the cytosol to the cell membrane, thus it has to be related to the viscosity of cytosol. It is clear that when the organism is in the starvation period, the composition of cytosol is changing [18][19][20]. In the work [9] authors have shown that in the cells group respectively.…”

Section: Relaxationsmentioning

confidence: 99%

“…This suggest the possible origin of this process. Every organism has reserve material mainly in the form of lipid droplets [19,20,24]. Such lipid droplets have been found in the hepatopancreas of Neocaridina davidi shrimps [25].…”

Section: Relaxationsmentioning

confidence: 99%

Application of dielectric spectroscopy in the dynamically changing biological system – case ofNeocaridina davidishrimp starvation

Włodarczyk

2020

Preprint

View full text Add to dashboard Cite

In this work, dielectric studies on Neocaridina davidi shrimps have been presented. The effect of starvation on dielectric properties such as conductivity or permittivity have been shown. It was found that the onset frequency of electrode polarization depends on starvation period, which is probably related to the cytoplasm viscosity. In the dielectric spectra of shrimps two relaxation processes have been identified i.e.  and  process. The  process is probably related to the counter ion polarization while  process to the mobility of macromolecules present in the body of a shrimp, mainly to the amount of lipids. It was also found that there is a difference in dielectric response between control group and the group regenerated after 14 day starvation period. Basing on dielectric response, one can conclude that the viscosity of cytoplasm of regenerated shrimps is higher and the cells are rich in the lipid droplets when compared to control group.

show abstract

“…The unique adaptations to the dark and nutrient poor subterranean habitat have fascinated biologists since the dawn of speleobiology more than 200 years ago. Studies have discovered numerous examples of convergent evolution including physiological adaptations such as low metabolic rates and other mechanisms to survive long-term starvation (Hervant et al 1997;Lipovsek et al 2018), and morphological adaptations such as elongation of limbs, loss of eyes and pigments (Poulson and White 1969;Christiansen 2004;Culver and Pipan 2009;Mammola 2018). However, very few studies have looked into behavioural adaptations to the hypogean environment (but see: Juberthie-Jupeau 1988;Hoch and Howarth 1993;Parzefall 2005), likely because in-situ studies of animal behaviour are fraught with difficulties given the scarcity and inaccessibility of most cave organisms.…”

Section: Introductionmentioning

confidence: 99%

A comparison of morphology and web geometry between hypogean and epigean species of Metellina orb spiders (family Tetragnathidae)

Hesselberg¹,

Simonsen²

2019

View full text Add to dashboard Cite

Citation: Hesselberg T, Simonsen D (2019) A comparison of morphology and web geometry between hypogean and epigean species of Metellina orb spiders (family Tetragnathidae). Subterranean Biology 32: 1-13. https://doi. AbstractStudies on the behaviour of subterranean animals are rare, mainly due to the problems with collecting data in these inaccessible habitats. Web-building cave spiders, however, leave a semi-permanent record of their foraging behaviour, which can relatively easily be recorded. In this study, we compare size, leg lengths and web characteristics between hypogean populations of Metellina merianae with its close wood-inhabiting relative M. mengei. We confirm previous observations that M. merianae does not show any obvious morphological and behavioural adaptions to a subterranean life-style, although individuals of the cave species were significantly larger and had webs with relatively fewer radii and capture spiral turns than M. mengei. We were, however, not able to determine if these findings indicate a transition towards behavioural adaptation to caves or if they are a result of behavioural flexibility in response to the different humidity and temperature between caves and woodland. Finally, we did not find any effect of cave characteristics on either the number of radii or the area of the M. merianae web.

show abstract

Changes in the midgut cells in the European cave spider, Meta menardi, during starvation in spring and autumn

Cited by 29 publications

References 47 publications

Changes in the midgut diverticula epithelial cells of the European cave spider, Meta menardi, under controlled winter starvation

Changes in the midgut diverticula epithelial cells of the European cave spider, Meta menardi, under controlled winter starvation

Application of dielectric spectroscopy in the dynamically changing biological system – case ofNeocaridina davidishrimp starvation

A comparison of morphology and web geometry between hypogean and epigean species of Metellina orb spiders (family Tetragnathidae)

Contact Info

Product

Resources

About