Circadian rhythm entrainment in flies and mammals

Circadian rhythms are a fundamental adaptation of living cells to the daily and seasonal fluctuation in light and temperature. Circadian oscillations persist in constant conditions; however, they are also phase-adjusted (entrained) by day-night cycles. It is this entrainability that provides for the proper phasing of the program, to the sequence of external changes that it has evolved to exploit. Synchronization of circadian oscillators with the outside world is achieved because light, temperature, or other external temporal cues, have acute effects on the levels of one or more of the clock's components. The consequences are ripples through the interconnected molecular loops, leading to a stable phase realignment of the endogenous rhythm generator and the external conditions. This review summarized the evolving knowledge of the different types, modes, and molecular processes of entrainment in flies and mammals.     

Peptidoglycan detection by mammals and flies

Peptidoglycan is an essential component of bacteria. The host exploits the peptidoglycan particular composition and uniqueness to bacteria for specific bacterial recognition. Insects and mammals accomplish this via receptors such as PGRP and Nod proteins.     

Taste and pheromone perception in mammals and flies

The olfactory systems of insects and mammals have analogous anatomical features and use similar molecular logic for olfactory coding. The molecular underpinnings of the chemosensory systems that detect taste and pheromone cues have only recently been characterized. Comparison of these systems in Drosophila and mouse uncovers clear differences and a few surprising similarities.     

Insulators and imprinting from flies to mammals

The nuclear factor CTCF has been shown to be necessary for the maintenance of genetic imprinting at the mammalian H19/Igf2 locus. MacDonald and colleagues now report in BMC Biology that the mechanisms responsible for maintaining the imprinted state in Drosophila may be evolutionarily conserved and that CTCF may also play a critical role in this process.     

Spindle regulation in neural precursors of flies and mammals

The mitotic spindle is the cellular scaffold that facilitates proper segregation of genetic material during cell division. Far from being static, the spindle is a dynamically regulated tool that can alter its size, shape and position during mitosis. Work in both insect and vertebrate systems has shown that regulation of this structure involves an array of highly conserved proteins. Moreover, it is now clear that tight regulation of the spindle during the process of neurogenesis is paramount to proper cell division and generation of the nervous system as a whole.     

Parasite-host relationship of flies and small mammals in the Omsk region

A generalized analysis of data on a flea fauna, range of their hosts in various natural zones, and features of parasite-host relationships between fleas and small mammals obtained in the Omsk province during long term researches in 1963-1997 is given. 35 flea species are recorded. The most mass species both on animals and in their nest is Ctenophthalmus assimilis; the numerous species are Amalareus penicilliger, Megabothros rectangulatus, M. walkeri, Peromyscopsylla silvatica, Ctenophthalmus unciatus, Palaropsylla sorecis, Doratopsilla birulai, Neopsylla pleskei, Hystrichopsylla talpae; the usual species--Ceratopsyllus garei, M. calcarifer, M. turbidus, Frontopsylla elata, Amphipsylla sibirica, A. kuznetzowi, Peromyscopsylla dasycnema, Radinopsylla integella, Catalagia dacenkoi. Other species are less numerous or infrequent. The general infection rate of the flea populations on rodents and insectivores makes 30.4%. For certain species it reaches 65.1% (on red-backed vole Cletrionomys rutilus), for regular groups--86.9% (on shrews of the genus Sorex). The greatest variety of the flea populations is observed on Microtus arvalis, the least one--on Sorex caecutiens and S. daphaenodon. In the nests of small mammals the variety of fleas is significantly lower. Based on the index of flea species relative "loyalty" to small mammals and their nest we have recognized 6 groups of fleas.     

Intracellular and extracellular alkaloids of Penicillium roqueforti

The alkaloid composition of mycelium and culture liquid filtrate of the fungus Penicillium roqueforti IBPM-F-141 was studied. The new metabolite--3,12-dihydroroquefortine, a derivative of roquefortine, the main component of the alkaloid fraction of this culture, has been isolated for the first time. The structure of 3,12-dihydroroquefortine was determined by chemical and physico-chemical methods. In addition to roquefortine and 3,12-dihydroroquefortine, representatives of a new alkaloid group, the clavine alkaloids, e. g. isofumigaclavine A, isofumigaclavine B and festuclavine, were also isolated and identified. The data on the content of these compounds in mycelium and culture medium are presented.     

Intracellular and extracellular ribonucleases of Bacillus intermedius

Endocellular and exocellular ribonucleases were studied in Bacillus intermedius. Two fractions of ribonucleases (Rf 0.72 and 0.96) were found to be associated with the cellular surface and seven fractions (Rf 0.1, 0.17, 0.33, 0.45, 0.72, 0.82 and 0.96) were detected in the cytoplasm. RNAase with Rf 0,096 had the highest activity and was repressed by inorganic orthophosphate. This RNase accumulated in the cell during the stationary growth phase just as the free enzyme form did in the culture medium. The immunological characteristics of these enzymes were identical as was shown by immunochemical analysis.     

The extracellular epidermal compartment of mammals

The structure and function of the intercorneocyte cement of the corneal layer of epidermis in mammals has been reviewed on the basis of the author's and published data. Two functions of the layer have been considered: a water-tight barrier and a desquamation. Chemical structure of the barrier has been characterized. Comparison of the barrier in water and terrestrial mammals suggest that the peculiarities of the barrier correlate with different pathways of keratinization. Factors that determine the adhesion have been described. The authors show the possibility to use natural models for studying the processes of keratinization and, in particular, functioning the intercellular compartment of the corneal layer.     

The maternal recognition of pregnancy in mammals

Progesterone secreted by the corpora lutea stimulates uterine secretion of nutrients required for embryonic growth. But progesterone also blocks maturation of ovarian follicles and oestrous behaviour. When conception fails, therefore, the corpora lutea must lyse, in order to allow a second ovulation and oestrus, while in pregnancy the corpora lutea must be maintained. A number of different endocrine mechanisms exist to ensure the corpora lutea are controlled appropriately depending on pregnancy status; among the best studied of these are the secretion by the developing conceptus of interferons (in ungulates) or chorionic gonadotropins (in primates). These and other mechanisms are reviewed.     

A mathematical model of pregnancy recognition in mammals

In this paper we develop a mathematical model of the luteal phase of the reproductive cycle in mammals with the aim to generate a systems understanding of pregnancy recognition. Pregnancy recognition is initiated by the production of interferon tau (IFNτ) by the growing conceptus. This ensures that the maternal corpus luteum (CL) remains viable to secrete progesterone, which is critical for providing a uterine microenvironment suitable for embryonic growth. Our mathematical model describes the interactions among the CL, the reproductive hormones and the hormone receptors in the uterus. It also characterises the complex interactions amongst the uterine oestrogen, progesterone and oxytocin receptors that control the sensitivity of the uterus to oestrogen, progesterone and oxytocin, respectively. The model is represented by a dynamical system and exhibits qualitative features consistent with the known experimental results in sheep. A key factor identified was a time-dependent threshold for the IFNτ signal below which the presence of the embryo might not be recognised and thus pregnancy would likely fail. Furthermore, the model indicated that if the IFNτ signal is later than around day 13 of the cycle, then pregnancy will not be recognised irrespective of the IFNτ concentration. The thresholds in the concentration and time of the IFNτ signal is a screening mechanism whereby only embryos of sufficient quality are able to prevent luteolysis (i.e. regression of the CL). The effect of progesterone secretion rate from the CL on pregnancy recognition was investigated. The model suggests that if the secretion rate is low then the initiation of the IFNτ signal is delayed, which in turn compromises the likelihood of a pregnancy being recognised by the CL. Furthermore, pregnancy recognition does not occur below a critical threshold in the progesterone secretion rate. In summary, the model can be used to identify the most favourable conditions for pregnancy recognition.     

Catecholaminergic regulation of ovarian function in mammals: current concepts

A review of the rapidly accumulating data in the literature continues to support the notion that catecholamines regulate ovarian function, and extends the complexity of catecholaminergic effects on the ovary via interactions with pituitary and adrenal hormones. It is clear that catecholamines affect growth and differentiation of ovarian follicles, but their role in follicular rupture during ovulation and in corpus luteum function remains unclear. The effects of catecholamines (mediated by membrane receptors) on ovarian function probably should be considered paracrine but classic endocrine regulation of ovarian function cannot be ruled out. Myogenic tonus of ovarian vasculature appears to be regulated by catecholamines, and estrogens may enhance adrenergic receptors in ovarian smooth muscle cells.     

Species concepts and the recognition of ancestors

Whether or not ancestral species can be recognised depends on the species concept adopted. A “metaspecies”; is a species that completely lacks autapomorphies, and which might (or might not) be ancestral to other species. Such taxa have been identified among both living and fossil organisms. Under the most commonly‐used species concepts (biological, evolutionary, phenetic, phylogenetic, ecological, recognition and cohesion), “metaspecies”; can be assumed to be ancestral. Even if the known members of a metaspecies are not ancestral to anything, parsimony dictates that the (as yet unknown) ancestral lineage is identical to the metaspecies and, under these species concepts, assignable to the same species. Only the cladistic and monophyletic species concepts would deny “metaspecies”; ancestral status, but these species concepts are problematical and have never been used by practising systematists.     

Oxytocin, vasopressin, and social recognition in mammals

While pheromones may act as social memory signals, oxytocin and vasopressin acting in the brain appear to be critical for the neural processing of olfactory signatures used for social discrimination. Evidence from a variety of laboratories using a range of animal models, as well as an array of molecular and pharmacological techniques, have helped to determine the neuroanatomical and functional roles oxytocin and vasopressin play in social cognition. In this review we discuss the considerable evidence for the roles of oxytocin and vasopressin in social recognition in rats and mice, as well as in offspring recognition in sheep and mate preference in monogamous voles.     

Phylogenetic species recognition and species concepts in fungi

The operational species concept, i.e., the one used to recognize species, is contrasted to the theoretical species concept. A phylogenetic approach to recognize fungal species based on concordance of multiple gene genealogies is compared to those based on morphology and reproductive behavior. Examples where Phylogenetic Species Recognition has been applied to fungi are reviewed and concerns regarding Phylogenetic Species Recognition are discussed.