Understanding the impact of barriers to onward migration; a novel approach using translocated fish.

River catchments worldwide are heavily fragmented by anthropogenic barriers, reducing their longitudinal connectivity and contributing to the decline of migratory fish populations. Direct impacts of individual barriers on migratory fish are well-established, but barrier impacts on onward migration are poorly understood, despite their relevance to evidence-based, catchment-scale, management of threatened species. This study investigated the upstream spawning migration of 352 acoustic tagged river lamprey (Lampetra fluviatilis), translocated upstream of two key barriers (R2: n = 60 & 59; R3: n = 59 & 52) compared to a control group (R1: n = 61 & 59), across two contrasting (dry and wet, n = 180 and 172) years in the River Yorkshire Ouse, England, to reveal the impact of barriers on the onward migration of upstream migrating fish. Release further upstream increased the degree of catchment penetration, with median distance upstream of R1 56.1% and 68.6% greater for lamprey released at R2 and R3 respectively. Median delays at the two downstream-most main river barriers by the control group were 23.8 and 5.4 days (2018/19) and 9.3 and 11.4 days (2019/20). However, impacts of delay were only observed on the time to reach spawning habitat, time to reach final assumed spawning location and speed of movement in one upper catchment tributary during 2019/20 whilst they were only observed on time to reach spawning habitat during 2018/19 and on assumed spawning location distance during 2019/20 in the other. Ultimately, limited impacts of delay at barriers on onward fish migration post-passage were observed but median catchment penetration was increased with consecutive release upstream. This study demonstrated the importance of a true understanding of barrier impacts to inform catchment-wide planning, evidence vital for management worldwide. Although the findings of this study do support the use of trap and transport as a measure to remediate barrier impacts on migration, fish passage engineering improvements or barrier removal, at structures shown to be the most inhibiting to fish migration should be considered the best and most sustainable option to improve barrier passage.

Immunohistochemical localisation of the creatine transporter in the rat brain.

Creatine (Cr) is required to maintain ATP levels in the brain. The transport of Cr across the blood-brain barrier and into neurones requires a specific creatine transporter (CRT). Mutations in the CRT gene (SLC6A8) result in a novel form of X-linked mental retardation, characterised by developmental delays, seizures and a complete absence of Cr from the brain. To identify cell types and regions that depend on Cr for energy metabolism we have determined the regional and cellular localisation of CRT protein in the rat brain using immunohistochemical techniques with a highly specific, affinity-purified, CRT antibody. The results show high levels of CRT localisation is associated with specific brain regions and certain cell types. The CRT is predominantly found in neurones. CRT immunoreactivity is particularly abundant in the olfactory bulb, granule cells of the dentate gyrus of the hippocampus, pyramidal neurones of the cerebral cortex, Purkinje cells of the cerebellum, motor and sensory cranial nerve nuclei in the brainstem and the dorsal and ventral horns of the spinal cord. Low levels of CRT were seen in the basal ganglia and white matter. Overall, CRT was found to show high intensities of labelling in the major motor and sensory regions of the forebrain, brainstem and spinal cord and forebrain regions associated with learning, memory and limbic functions. It is hypothesised that regions with high CRT expression are likely to have high metabolic ATP requirements and that areas with low CRT levels are those regions which are particularly vulnerable in neurodegenerative diseases.

Cysteine 144 in the third transmembrane domain of the creatine transporter is located close to a substrate-binding site.

All creatine transporters contain a cysteine residue (Cys(144)) in the third transmembrane domain that is not present in other members of the Na+,Cl(-)-dependent family of neurotransmitter transporters. Site-directed mutagenesis and reaction with methane thiosulfonates were used to investigate the importance of Cys(144) for transporter function. Replacement of Cys(144) with Ser did not significantly affect the kinetics or activity of the transporter, whereas a C144A mutant had a higher K(m) (0.33 compared with 0.18 mm). Substitution of Cys(144) with Leu gave a mutant with a 5-fold higher K(m) and a reduced specificity for substrate. Low concentrations of 2-aminoethyl methanethiosulfonate (MTSEA) resulted in rapid inactivation of the creatine transporter. The C144S mutant was resistant to inactivation, indicating that modification of Cys(144) was responsible for the loss of transport activity. Creatine and analogues that function as substrates of the creatine transporter were able to protect from MTSEA inactivation. Na+ and Cl(-) ions were not necessary for MTSEA inactivation, but Na+ was found to be important for creatine protection from inactivation. Our results indicate that cysteine 144 is close to the binding site or part of a permeation channel for creatine.

Creatine accumulation and exchange by HEK293 cells stably expressing high levels of a creatine transporter.

We have generated a stable HEK293 cell line expressing high levels of a creatine transporter (CREAT). This cell line (HEK293-CREAT) was used to study the properties of CREAT in terms of the accumulation and release of creatine. HEK293-CREAT cells accumulated high steady state levels of creatine under saturating creatine levels (approx. 25-fold higher intracellular creatine levels than seen in control cells). The accumulation of high levels of creatine affected [3H]creatine uptake by decreasing the Vmax for transport. High intracellular creatine levels were maintained in the absence of extracellular creatine. External creatine stimulated the release of stored creatine by an exchange mechanism dependent on extracellular Na+. These studies have shown that cellular creatine levels can be affected by the amount of creatine transporter in the membrane and exchange through the creatine transporter. These findings highlight the importance of the creatine transporter in the maintenance of intracellular creatine levels.

Euglena gracilis chloroplast ribosomal RNA transcription units. Nucleotide sequence polymorphism in 5 S rRNA genes and 5 S rRNAs.

The three tandemly repeated ribosomal RNA operons from the chloroplast genome of Euglena gracilis Klebs, Pringsheim Strain Z each contain a 5 S rRNA gene distal to the 23 S rRNA gene (Gray, P.W., and Hallick, R.B. (1979) Biochemistry 18, 1820-1825). We have cloned two distinct 5 S rRNA genes, and determined the DNA sequence of the genes, their 5'- and 3'-flanking sequences, and the 3'-end of the adjacent 23 S rRNA genes. The two genes exhibit sequence polymorphism at five bases within the "procaryotic loop" coding region, as well as internal restriction endonuclease site heterogeneity. These restriction endonuclease site polymorphisms are evident in chloroplast DNA, and not just the cloned examples of 5 S genes. Chloroplast 5 S rRNA was isolated, end labeled, and sequenced by partial enzymatic degradation. The same polymorphisms found in 5 S rDNA are present in 5 S rRNA. Therefore, both types of 5 S rRNA genes are transcribed and are present in chloroplast ribosomes.

Synthesis of some steroid spin labels.

An improved synthesis of spin-labeled cortisol, cortisone, and testosterone using N,N'-cyclohexylcarbodiimide (DCC) is reported. The spin labeled steroids are shown to result from the esterification at the most reactive C(21) and C(17) hydroxyl groups. A mild and high yield oxidation of cortisol spin label to cortisone spin label by chromium trioxide-pyridine is also discussed.

Euglena gracilis chloroplast ribosomal RNA transcription units. II. Nucleotide sequence homology between the 16 S--23 S ribosomal RNA spacer and the 16 S ribosomal RNA leader regions.

The DNA sequences of two segments of the ribosomal RNA transcription units of Euglena gracilis Pringsheim strain Z chloroplast DNA have been determined. The first is from the 16 S to 23 S rRNA spacer region. The nucleotide sequence determined includes 64 bp from the 3'-end of the 16 S rRNA gene, the adjacent 87-bp spacer containing 68A-T base pairs, a tRNAIle gene, a 9-bp spacer, a tRNAAla gene, a spacer of approximately 15 bp, and the first 120 bp from the 5'-end of the 23 S rRNA gene. The gene organization of the 16 S to 23 S rRNA spacer, the identity of the tRNA genes, and the tRNA anticodons for the E. gracilis rRNA transcription units are identical with that of the rrnA, D, and X operons of Escherichia coli. The second DNA segment which was sequenced is from a region preceding the 5'-end of the 16 S rRNA gene. Within a continuous region of 189 bp in this 16 S rRNA leader sequence, 68% of the bases are homologous to the 16 S rRNA to 23 S rRNA spacer region. This homology includes the 3'-end of the 16 S rRNA gene, the adjacent spacer, and a complete "pseudo" tRNAIle gene. This leader sequence which has the same polarity as the rRNA transcripts, is flanked by nucleotide sequences resembling partial tRNA genes.