No evidence for presence of maternal mitochondrial DNA in the sperm of Mytilus galloprovincialis males

Species of the mussel family Mytilidae have a special mitochondrial DNA (mtDNA) transmission system, known as doubly uniparental inheritance (DUI), which consists of a maternally inherited (F) and a paternally inherited (M) mitochondrial genome. Females are normally homoplasmic for the F genome and males are heteroplasmic mosaics, with their somatic tissues dominated by the maternal and their gonads dominated by the paternal genome. Several studies have indicated that the maternal genome may often be present in the male germ line. Here we report the results from the examination of mtDNA in pure sperm from more than 30 males of Mytilus galloprovincialis. In all cases, except one, we detected only the M genome. In the sperm of one male, we detected a paternal genome with an F-like primary sequence that was different from the sequence of the maternal genome in the animal's somatic tissues. We conclude that the male germ line is protected against invasion by the maternal genome. This is important because fidelity of gamete-specific transmission of the two mitochondrial genomes is a basic requirement for the stability of DUI.     

Hamster sperm glycine receptor: evidence for its presence and involvement in the acrosome reaction

Recent reports have provided evidence for the presence of amino acid neurotransmitter receptor/chloride channels in human and porcine spermatozoa and their involvement in the acrosome reaction (AR). In this work we investigated whether a glycine receptor (GlyR) was present in golden hamster sperm, and whether it had a role in the hamster AR. The neuronal GlyR agonist glycine, stimulated in a dose-dependent manner, the AR of hamster spermatozoa previously capacitated for at least 3 hr. This stimulation was completely inhibited by 50 microM (+)-bicuculline and by concentrations of strychnine as low as 10-50 nM; both agents are antagonists of neuronal GlyR when used at the concentrations reported in this study. beta-Alanine, another agonist of the neuronal GlyR, also stimulated the AR. The AR-stimulatory effect of this compound was completely abolished by 50 nM strychnine. The inhibitory effect of strychnine on the glycine-induced hamster sperm AR was completely overcome by subsequent treatment with the calcium ionophore ionomycin, demonstrating that the strychnine effect was specific for GlyR. Additional binding studies with (3)[H]-strychnine, the typical radioligand used to detect GlyR in several cells, demonstrated for the first time the presence of specific binding sites for strychnine in the hamster spermatozoa. Interestingly, binding increased during in vitro capacitation, particularly in those sperm suspensions showing high percentages of AR. Taken together these results strongly suggest the presence of a GlyR in the hamster spermatozoa, with a role in the AR when activated.     

Electrophysiological evidence for the presence of cystic fibrosis transmembrane conductance regulator (CFTR) in mouse sperm

Mammalian sperm must undergo a maturational process, named capacitation, in the female reproductive tract to fertilize the egg. Sperm capacitation is regulated by a cAMP/protein kinase A (PKA) pathway and involves increases in intracellular Ca²⁺, pH, Cl^?, protein tyrosine phosphorylation, and in mouse and some other mammals a membrane potential hyperpolarization. The cystic fibrosis transmembrane conductance regulator (CFTR), a Cl^? channel modulated by cAMP/PKA and ATP, was detected in mammalian sperm and proposed to modulate capacitation. Our whole‐cell patch‐clamp recordings from testicular mouse sperm now reveal a Cl^? selective component to membrane current that is ATP‐dependent, stimulated by cAMP, cGMP, and genistein (a CFTR agonist, at low concentrations), and inhibited by DPC and CFTR_inh‐172, two well‐known CFTR antagonists. Furthermore, the Cl^? current component activated by cAMP and inhibited by CFTR_inh‐172 is absent in recordings on testicular sperm from mice possessing the CFTR ΔF508 loss‐of‐function mutation, indicating that CFTR is responsible for this component. A Cl^? selective like current component displaying CFTR characteristics was also found in wild type epididymal sperm bearing the cytoplasmatic droplet. Capacitated sperm treated with CFTR_inh‐172 undergo a shape change, suggesting that CFTR is involved in cell volume regulation. These findings indicate that functional CFTR channels are present in mouse sperm and their biophysical properties are consistent with their proposed participation in capacitation. J. Cell. Physiol. 228: 590–601, 2013. © 2012 Wiley Periodicals, Inc.     

Hydrogen-exchange evidence for distinct structural classes in globular proteins

Exchange-rate probability-density functions (pdf) have been calculated for lysozyme hydrogen-exchange data by numerical Laplace inversion over the temperature range 5–45°C. The smoothest numerical solutions show three broad overlapping peaks. Analysis of the temperature dependence of the cumulative exchange-rate distributions provides the model-independent probability-density function for the activation energies. For the most rapidly exchanging protons, the activation energies are low, consistent with hydroxyl-ion catalysis in the protein–water interface. The second peak of the exchange-rate pdf's contains those protons located in regions of lower motility we call “matrices,” for which exchange rates are limited by gated-diffusion of the hydroxyl-ion catalyst. The most slowly exchanging protons are located on groups forming strong, dense “knot” structures, identified by neutron-diffraction and nmr data as clustered segments of β-sheet with well-organized hydrogen bonding and sections of the internal faces of α-helices. Exchange from knot structures occurs through local disordering with little loss of strength or stability to expose one or more protons at a time for exchange. Knots appear to be responsible for the two-state character of thermal unfolding that occurs by cooperative disruption of the dominant structures of this type. Below about 55°C, all protons exchange from folded states. Contributions to exchange from unfolding processes occur only at temperatures above 55°C. There is a qualitative difference between the two types of structures indicated by the appearance of two and only two enthalpy–entropy compensation patterns. The compensation temperature, T_c, for the matrices is about 470 K; that for the knots, about 360 K. The preservation of rank-order with temperature change is shown to be a consequence of the fact that all exchange rates in the slow and very slow peaks of the pdf lie on one or the other of the two compensation lines. Although the same electrostatic factors are present in all parts of the protein, we have been forced to conclude that given certain necessary geometric possibilities, these factors cooperate to produce the knots. The knots appear to be the most significant structural element in globular proteins responsible for the structural form of the matrix regions and the dynamic behavior of the protein interior. The knots have high density and low permeability to water, hydroxyl ion, etc., and are probably the explanation for the very low compressibilities, the matrices being nearly mechanically transparent. The knots must make some contribution to folded stability, but it is not clear that this contribution is large. Their major thermodynamic function is to establish kinetic stability; that is, to make the activation free energy for unfolding high. The most important factor in the existence of knots appears to be the ease with which hydrogen bonds adapt in length, angle, and strength to local electrostatic conditions. In proteins, as in water, adaptation is cooperative in local groups of hydrogen bonds, and as in water, this cooperation is enhanced by contact with aromatic and aliphatic groups.     

Electron microscope study of the structures of the Bacillus subtilis prophages, SPO2 and phi105

Circular duplex structures of the correct length are observed in the electron microscope in hybridization mixtures of lysogen DNA and mature phage DNA for the case of the temperate Bacillus subtilis bacteriophage SPO2. This result shows that the sequence order of the prophage is a circular permutation of that of the mature phage. By making heteroduplexes of prophage DNA with that of the SPO2 deletion mutants, R90 and S25, the att site of the phage has been mapped at 61.2 ± 0.6% from one end of the mature phage DNA, which has a length of 38,600 base pairs. In the same co-ordinate system, the R90 deletion extends from 58.9 ± 0.7 to 66.8 ± 0.8% on the SPO2 chromosome, whereas the S25 deletion extends from 63.2 ± 0.6 to 66.9 ± 0.7%. In similar experiments with lysogen and mature phage DNA's of the temperate B. subtilis phage, φ105, no circular structures were seen. This result shows that the sequence order in the prophage and the phage are colinear, without circular permutation.     

Tetrahymena strives to maintain the fluidity interrelationships of all its membranes constant. Electron microscope evidence

When cells of Tetrahymena pyriformis, strain NT-1, were chilled from their growth temperature of 39.5 degrees C to lower temperatures, the plasma membrane, outer alveolar, nuclear, outer mitochondrial, food vacuolar, and endoplasmic reticulum membranes each responded in a fashion quite characteristic of the membrane type. In most cases a distinctive rearrangement of intramembrane particles, as discerned by freeze-fracture electron microscopy, began abruptly at a definitive temperature. By comparing the freeze-fracture patterns of membranes in cells grown at 39.5, 27, and 15 degrees C, it was shown that the initial particle rearrangement in a given membrane always occurred at a fixed number of degrees below the growth temperature of the cell. Gradual chilling of a cell grown at constant temperature induced these membrane changes first in the outer alveolar membrane, then, in order of decreasing response to temperature, in the endoplasmic reticulum, outer mitochondrial membrane, nuclear envelope, and vacuolar membrane. The normally stable relationships between the physical properties of the several membrane types could in some cases be reversed, but only temporarily, by fatty acid supplementation or during the initial phases of acclimation to growth at a different temperature. The system provides a unique opportunity to study the effects of environmental change upon the physical properties of several functionally distinct but metabolically interrelated membranes within a single cell.     

Experimental evidence for the evolution of numerous,tiny sperm via sperm competition

Sperm competition, when sperm from different males compete to fertilize a female's ova, is a widespread and fundamental force in the evolution of animal reproduction. The earliest prediction of sperm competition theory was that sperm competition selected for the evolution of numerous, tiny sperm, and that this force maintained anisogamy. Here, we empirically test this prediction directly by using selective breeding to generate controlled and independent variance in sperm size and number traits in the cricket Gryllus bimaculatus. We find that sperm size and number are male specific and vary independently and significantly. We can therefore noninvasively screen individuals and then run sperm competition experiments between males that differ specifically in sperm size and number traits. Paternity success across 77 two-male sperm competitions (each running over 30-day oviposition periods) shows that males producing both relatively small sperm and relatively numerous sperm win competitions for fertilization. Decreased sperm size and increased sperm number both independently predicted sperm precedence. Our findings provide direct experimental support for the theory that sperm competition selects for maximal numbers of miniaturized sperm. However, our study does not explain why G. bimaculatus sperm length persists naturally at approximately 1 mm; we discuss possibilities for this sperm size maintenance.