Ornithodiplostomum ptychocheilus: migration to the brain of the fish intermediate host, Pimephales promelas.

Migration of cercariae of the diplostomatid trematode, Ornithodiplostomum ptychocheilus, to the brain of the fathead minnow, Pimephales promelas, takes place via directed, nonrandom movement. Penetration of the fish epidermis is rapid and is essentially complete by 2 hr postinfection. Migration to the central nervous system occurs almost exclusively via the general body musculature and connective tissue, although a few cercariae gain direct access to the nervous system via the eyes. Cercariae enter either the neural canal and spinal cord, or the brain via the spinal or cranial nerves and their associated foramina, although cercariae appear to remain in (on) these peripheral nerves for only a short time. Cercariae associated with cranial nerves continue to the brain. Those becoming associated with spinal nerves travel up the neural canal and (or) spinal cord to the brain. Data suggest that most arrive at the brain via the neural canal and spinal cord. Within the brain, most developing metacercariae (neascus-type) occur in the optic lobes and cerebellum. Whether this is “selective localization” or merely the result of the larger space afforded by these brain regions could not be determined.     

Light and electron microscopical study of Nosema eurytremae

A nuclear-polyhedrosis virus (NPV) of the silkworm, Bombyx mori, which forms an icosahedral inclusion body, was transmitted to larvae of the rice stem borer, Chilo suppressalis. Serial passages of Bombyx NPV in the alternate host by injecting the supernatant of diseased hemolymph produced inclusion bodies with cuboidal and other shapes that differed from the original shape formed in Bombyx. These different shapes increased with times of passages, and after the twelfth passage, only cuboidal inclusion bodies were formed. The icosahedral inclusion bodies in B. mori and the cuboidal inclusion bodies in C. suppressalis occluded singly enveloped virions of the same size (350 × 75 nm), but the cuboidal inclusion bodies contained only a few virions and a large number of membraneous spherical structures. The formation process of the cuboidal inclusion body differed from that of the icosahedral. At first, irregularly branched inclusion bodies containing “vacant” spaces appeared in the infected nuclei. The bodies grew larger with the deposition of protein in the spaces between the branches, and this was accompanied with the occlusion of a large number of membraneous structures formed in the vicinity of the inclusion bodies, which became cuboidal in shape.     

The complete mitochondrial genome of the Sichuan taimen (Hucho bleekeri): repetitive sequences in the control region and phylogenetic implications for Salmonidae

The complete mitochondrial DNA genome of the Sichuan taimen (Hucho bleekeri) was determined by the long and accurate polymerase chain reaction (LA-PCR) and primer walking sequence method. The entire mitochondrial genome of this species is 16,997 bp in length, making it the longest among the completely sequenced Salmonidae mitochondrial genomes. It consists of two ribosomal RNA (rRNA) genes, 13 protein-coding genes, 22 transfer RNA (tRNA) genes, and one control region (CR). The gene arrangement, nucleotide composition, and codon usage pattern of the mitochondrial genome are similar to those of other teleosts. A T-type mononucleotide microsatellite and an 82 bp tandem repeat were identified in the control region, which were almost identical among the three H. bleekeri individuals examined. Both phylogenetic analyses based on 12 concatenated protein-coding genes of the heavy strand and on just the control region show that H. bleekeri is a basal species in Salmoninae. In addition, Salmo, Salvelinus and Oncorhynchus all represent monophyletic groups, respectively. All freshwater species occupied basal phylogenetic positions, and also possessed various tandem repeats in their mitochondrial control regions. These results support established phylogenetic relationships among genera in Salmonidae based on morphological and molecular analyses, and are consistent with the hypothesis that Salmonidae evolved from freshwater species.     

利用EM和OL处理猪粪的效果研究

The effects of EM and OL on the color,pHvalue,stink and the various kinds of harmful microbes of pig manure were analyzed.The results show that EM and OL could significantly reduce the stink and restrain the number of harmful microbes.At the same time,the rotting process of pig manure was accelerated,and the number of flies around pig manure reduced.     

Multiple inhibitory pathways shape odor-evoked responses in lobster olfactory projection neurons

This study characterizes odor-evoked responses of the glomerular output neurons of the spiny lobster olfactory lobe, and implicates previously identified γ-aminobutyric acid (GABA)- and histamine-mediated inhibitory pathways in shaping these responses. Odor-evoked responses were more complex than electrically evoked responses, with up to three distinct components: a brief, short-latency (fast) depolarization, a longer-duration, longer-latency (slow) depolarization, and a slow hyperpolarization. Seventy-seven percent of all responses contained the hyperpolarization, while only 31% and 23% contained the fast and slow depolarizations, respectively. The broader tuning of the hyperpolarization relative to the other two components suggests that the hyperpolarization mediates lateral inhibitory interactions across olfactory glomeruli. Perfusing the brain with the GABA-receptor antagonist picrotoxin increased the amplitude of the hyperpolarization, while the histamine-receptor antagonist cimetidine decreased the hyperpolarization in some instances but increased it in others. Pharmacological enhancement or suppression of the hyperpolarization could mask or unmask, respectively, the slow depolarization. Both antagonists could also cause the appearance of the fast depolarization when it was not apparent prior to treatment. We conclude that GABA- and histamine-mediated inhibition contributes to the overall pattern of the response of projection neurons to odors by regulating the relative strength of these three distinct types of input. Accepted: 17 September 1997     

Canonical Wnt signalling requires the BMP pathway to inhibit oligodendrocyte maturation

OLs (oligodendrocytes) are the myelinating cells of the CNS (central nervous system), wrapping axons in conductive sheathes to ensure effective transmission of neural signals. The regulation of OL development, from precursor to mature myelinating cell, is controlled by a variety of inhibitory and inductive signalling factors. The dorsal spinal cord contains signals that inhibit OL development, possibly to prevent premature and ectopic precursor differentiation. The Wnt and BMP (bone morphogenic protein) signalling pathways have been identified as dorsal spinal cord signals with overlapping temporal activity, and both have similar inhibitory effects on OL differentiation. Both these pathways feature prominently in many developmental processes and demyelinating events after injury, and they are known to interact in complex inductive, inhibitive and synergistic manners in many developing systems. The interaction between BMP and Wnt signalling in OL development, however, has not been extensively explored. In the present study, we examine the relationship between the canonical Wnt and BMP pathways. We use pharmacological and genetic paradigms to show that both Wnt3a and BMP4 will inhibit OL differentiation in vitro. We also show that when the canonical BMP signalling pathway is blocked, neither Wnt3a nor BMP4 have inhibitory effects on OL differentiation. In contrast, abrogating the Wnt signalling pathway does not alter the actions of BMP4 treatment. Our results indicate that the BMP signalling pathway is necessary for the canonical Wnt signalling pathway to exert its effects on OL development, but not vice versa, suggesting that Wnt signals upstream of BMP.     

Axoskeletal proteins prevent oligodendrocyte from toxic injury by upregulating survival,proliferation, and differentiation in vitro

Neurofilaments (NF) are detected in the cerebrospinal fluid of multiple sclerosis (MS) patients, and their concentration correlates with disease severity. We recently demonstrated that NF and co-isolated proteins increase the proliferation and differentiation of oligodendrocytes (OL) in vitro. If these proteins are released in the extracellular environment in MS, they might then regulate remyelination by OL. To test this hypothesis we took advantage of a paradigm of OL toxic injury using lysophosphatidyl choline (LPC), which decreases proliferation and differentiation of surviving cells, and destroys myelin-like membranes. In OL cultures that have been treated with LPC, NF fractions as well as tubulin (TUB) significantly improved recovery: the number of OL progenitors (OLP, A2B5+ cells) increased by 100% and their proliferation by 200%, whereas differentiated (CNP+) and mature (MBP+) cells increased by 150% compared to cultures treated with LPC alone. When added at the time of LPC treatment, NF and TUB protected OL from LPC toxicity; they increased OLP by 90%, as well as the number of CNP+ and MBP+ OL by 65–110%, respectively, compared to cultures treated only with LPC. These effects were specific since irrelevant proteins (actin, skin proteins) were ineffective. This demonstrates that NF and TUB protect OL and increase OLP proliferation, as well as their survival, when challenged with LPC, without delaying differentiation and maturation in vitro. Thus, NF and TUB delivered following axonal damage in MS could participate in the regulation of remyelination through this process.     

Hybridization between mitochondrial heavy strand tDNA and expressed light strand tRNA modulates the function of heavy strand tDNA as light strand replication origin

Mitochondrial heavy strand (HS) tDNA codes for tRNAs and frequently functions as the light strand (LS) replication origin (OL). During replication, HS sites remain single-stranded until their LS complement is synthesized, a state prone to hydrolytic deaminations of C → T and A → G, causing genome-wide deamination gradients starting at OLs and proportional to time spent single-stranded. Gradient strength is proportional to OL formation by HS tDNAs. Hypothetically, hybridization between HS tDNA and its expressed complement tRNA should decrease OL activity for LS-, but not HS-encoded tRNAs. Comparisons between primate genomes and between pathogenic and non-pathogenic human polymorphisms both confirm corresponding predictions on OL activity. In primates, strengths of deamination gradients starting at tDNAs functioning as OLs and coding for LS tRNAs decrease proportionally to stabilities of HS tDNA-LS tRNA hybridization; not so for HS tRNAs. Similarly, in mutants of human HS tDNAs coding for LS tRNAs, pathogenic mutants of tDNAs usually not forming OLs form weaker HS tDNA-LS tRNA duplexes than non-pathogenic ones; the opposite is true for tDNAs usually forming OLs. No trend was detected for HS tDNA coding for HS tRNA. tDNA-tRNA hybridization of the modal (most frequent) human tDNA sequence is more stable than of other, rarer non-pathogenic polymorphisms, suggesting similar but weaker mutational effects on tDNA/tRNA functions than in pathogenic mutants. HS tDNA-LS tRNA hybridization appears to compete with OL formation by HS tDNA self-hybridization.     

Long bone histology of Ophiacodon reveals the geologically earliest occurrence of fibrolamellar bone in the mammalian stem lineage

Shared histological characteristics have been observed in the bone matrix and vascularity between Ophiacodontidae and the later therapsids (Synapsida). Historically, this coincidence has been explained as simply a reflection of the presumed aquatic lifestyle of Ophiacodon or even a sign of immaturity. Here we show, by histologically sampling an ontogenetic series of Ophiacodon humeri, as well as additional material, the existence of fibrolamellar bone (FLB) in the postcranial bones of a pelycosaur. Our findings have reaffirmed what previous studies first described as fast growing tissue, and by proxy, have disproven that the highly vascularized cortex is simply a reflection of young age. This tissue demonstrates the classic histological characteristics of true FLB. The cortex consists of primary osteons in a woven bone matrix and remains highly vascularized throughout ontogeny, providing evidence for fast skeletal growth. Overall, the FLB tissue we have described in Ophiacodon is more advanced or “mammal-like” in terms of the osteonal development, bone matrix, and skeletal growth than what has been described thus far for any other pelycosaur taxon. With regards to the histological record, our results remain inconclusive as to the preferred ecology of Ophiacodon due to a similar cortical vascularity pattern exhibited by other carnivorous pelycosaurs. Our findings have set the evolutionary origins of FLB and high skeletal growth rates back approximately 20 million years to the Early Permian, and by phylogenetic extension perhaps the Late Carboniferous.     

Physical and genetic map of the organomercury resistance (Omr) and inorganic mercury resistance (Hgr) loci of the IncM plasmid R831b

Tn7 insertion mutagenesis has been used to facilitate the generation of a physical (restriction endonuclease) and genetic map of the IncM plasmid, R831b. The only selectable phenotypes carried by this 90-kb conjugative plasmid are resistances to inorganic mercury [Hg(II)] and to organomercury compounds. Mutants in the Hgr locus of R831b complemented previously described mutants in the mer operon of the IncFII plasmid R100, indicating functional homology of the locus in each of these different plasmids. However, the R831b Hgr locus is not notably similar in restriction site pattern to either the mer operon of R100 or the mercury resistance transposon, Tn501. Although the enzymes they encode are co-ordinately regulated, the Omr locus of R831b maps approx. 13.5 kb away from the Hgr locus. Three insertions which affect neither phenotype lie between the Hgr and Omr loci; thus, the loci are separated both physically and genetically. One mutant was obtained which tentatively identifies the position of the Tra locus of R831b as adjacent to the Hgr locus.