T. Hankeln

Expression analysis of neuroglobin mRNA in rodent tissues

Neuroglobin is a respiratory protein which was reported to be preferentially expressed in the vertebrate brain. Here we present the first detailed analysis of the expression of neuroglobin in mouse and rat tissues. Neuroglobin mRNA was detected in all brain areas studied. Most, but not all, nerve cells were labeled, suggesting differential expression of Ngb. Neuroglobin mRNA was detected in the peripheral nervous system, explaining previous northern hybridization signals in organs other than the brain. Substantial neuroglobin expression was also found in metabolically active endocrine tissues such as the adrenal and pituitary glands. The granule localization of neuroglobin transcripts in various neuronal extensions let us speculate that peripheral translation of neuroglobin protein occurs. This could have important functional consequences for synaptic plasticity, an active metabolic process that needs large amounts of oxygen. The hybridization signals suggest that the local concentration of neuroglobin is sufficient for its putative primary function as an oxygen-supplying protein.

The amphibian globin gene repertoire as revealed by the Xenopus genome

The draft genome sequence of the Western clawed frog Xenopus (Silurana) tropicalis facilitates the identification, expression analysis and phylogenetic classification of the amphibian globin gene repertoire. Frog and mammalian neuroglobin display about 67% protein sequence identity, with the expected predominant expression in frog brain and eye. Frog and mammalian cytoglobins share about 69% of their amino acids, but the frog protein lacks the mammalian-type extension at the C-terminus. Like in mammals, X. tropicalis cytoglobin is expressed in many organs including neural tissue. Neuroglobin and cytoglobin genomic regions are syntenically conserved in all vertebrate classes. Frog and fish globin X show only 57% amino acid identity, but gene synteny analysis confirms orthology. The expression pattern of X. laevis globin X differs from that in fish, with a prominent expression in the eye and weak expression in most other examined tissues. Globin X is possibly present as two paralogous copies in X. tropicalis, with one copy showing transition stages of non-functionalization. The amphibian genome contains a previously unknown globin type (tentatively named ‘globin Y’) which is expressed in a broad range of tissues and is distantly related to the cytoglobin lineage. The globin Y gene is linked to a cluster of larval and adult hemoglobin α and β genes which contains substantially more paralogous hemoglobin gene copies than previously published. Database and gene synteny analyses confirm the absence of a myoglobin gene in X. tropicalis.

Interspecies comparison of neuroglobin, cytoglobin and myoglobin: Sequence evolution and candidate regulatory elements

Neuroglobin and cytoglobin are two novel members of the vertebrate globin family. Their physiological role is poorly understood, although both proteins bind oxygen reversibly and may be involved in cellular oxygen homeostasis. Here we investigate the selective constraints on coding and non-coding sequences of the neuroglobin and cytoglobin genes in human, mouse, rat and fish. Neuroglobin and cytoglobin are highly conserved, displaying very low levels of non-synonymous nucleotide substitutions. An oxygen supply function predicts distinct modes of gene regulation, involving hypoxia-responsive transcription factors. To detect conserved candidate regulatory elements, we compared the neuroglobin and cytoglobin genes in mammals and fish. The myoglobin gene was included to test if it also contains hypoxia-responsive regulatory elements. Long conserved non-coding sequences, indicative of gene-regulatory elements, were found in the cytoglobin and myoglobin, but not in the neuroglobin gene. Sequence comparison and experimental data allowed us to delimit upstream regions of the neuroglobin and cytoglobin genes that contain the putative promoters, defining candidate regulatory regions for functional tests. The neuroglobin and the myoglobin genes both lack conserved hypoxia-responsive elements (HREs) for transcriptional activation, but contain conserved hypoxia-inducible mRNA stabilization signals in their 3′ untranslated regions. The cytoglobin gene, in contrast, harbors both conserved HREs and mRNA stabilization sites, strongly suggestive of an oxygen-dependent regulation.

When the brain goes diving: glial oxidative metabolism may confer hypoxia tolerance to the seal brain.

Deep diving mammals have developed strategies to cope with limited oxygen availability when submerged. These adaptations are associated with an increased neuronal hypoxia tolerance. Brain neurons of the hooded seal Cystophora cristata remain much longer active in hypoxic conditions than those of mice. To understand the cellular basis of neuronal hypoxia tolerance, we studied neuroglobin and cytochrome c in C. cristata brain. Neuroglobin, a respiratory protein typically found in vertebrate neurons, displays three unique amino acid substitutions in hooded seal. However, these substitutions unlikely contribute to a modulation of O(2) affinity. Moreover, there is no significant difference in total neuroglobin protein levels in mouse, rat and seal brains. However, in terrestrial mammals neuroglobin resided exclusively in neurons, whereas in seals neuroglobin is mainly located in astrocytes. This unusual localization of neuroglobin is accompanied by a shift in the distribution of cytochrome c. In seals, this marker for oxidative metabolism is mainly localized in astrocytes, whereas in terrestrial mammals it is essentially found in neurons. Our results indicate that in seals aerobic ATP production depends significantly on astrocytes, while neurons rely less on aerobic energy metabolism. This adaptation may imbue seal neurons with an increased tolerance to hypoxia and potentially also to reactive oxygen species, and may explain in part the ability of deep diving mammals to sustain neuronal activity during prolonged dives.

Oxygen binding properties of non-mammalian nerve globins

Oxygen‐binding globins occur in the nervous systems of both invertebrates and vertebrates. While the function of invertebrate nerve haemoglobins as oxygen stores that extend neural excitability under hypoxia has been convincingly demonstrated, the physiological role of vertebrate neuroglobins is less well understood. Here we provide a detailed analysis of the oxygenation characteristics of nerve haemoglobins from an annelid (Aphrodite aculeata), a nemertean (Cerebratulus lacteus) and a bivalve (Spisula solidissima) and of neuroglobin from zebrafish (Danio rerio). The functional differences have been related to haem coordination: the haem is pentacoordinate (as in human haemoglobin and myoglobin) in A. aculeata and C. lacteus nerve haemoglobins and hexacoordinate in S. solidissima nerve haemoglobin and D. rerio neuroglobin. Whereas pentacoordinate nerve globins lacked Bohr effects at all temperatures investigated and exhibited large enthalpies of oxygenation, the hexacoordinate globins showed reverse Bohr effects (at least at low temperature) and approximately twofold lower oxygenation enthalpies. Only S. solidissima nerve haemoglobin showed apparent cooperativity in oxygen binding, suggesting deoxygenation‐linked self‐association of the monomeric proteins. These results demonstrate a remarkable diversity in oxygenation characteristics of vertebrate and invertebrate nerve haemoglobins that clearly reflect distinct physiological roles.

Comparative genomic sequencing reveals a strikingly similar architecture of a conserved syntenic region on human chromosome 11p15.3 (including gene ST5) and mouse chromosome 7

Comparative genomics is a superior way to identify phylogenetically conserved features like genes or regions involved in gene regulation. The comparison of extended orthologous chromosomal regions should also reveal other characteristic traits essential for chromosome or gene function. In the present study we have sequenced and compared a region of conserved synteny from human chromosome 11p15.3 and mouse chromosome 7. In human, this region is known to contain several genes involved in the development of various disorders like Beckwith-Wiedemann overgrowth syndrome and other tumor diseases. Furthermore, in the neighboring chromosome region 11p15.5 extensive imprinting of genes has been reported which might extend to region 11p15.3. The analysis of approximately 730 kb in human and 620 kb in mouse led to the identification of eleven genes. All putative genes found in the mouse DNA were also present in the same order and orientation in the human chromosome. However, in the human DNA one putative gene of unknown function could be identified which is not present in the orthologous position of the mouse chromosome. The sequence similarity between human and mouse is higher in transcribed and exon regions than in non-transcribed segments. Dot plot analysis, however, reveals a surprisingly well-conserved sequence similarity over the entire analyzed region. In particular, the positions of CpG islands, short regions of very high GC content in the 5′ region of putative genes, are similar in human and mouse. With respect to base composition, two distinct segments of significantly different GC content exist as well in human as in the mouse. With a GC content of 45% the one segment would correspond to “isochore H1” and the other segment (39% GC in human, 40% GC in mouse) to “isochore L1/L2”. The gene density (one gene per 66 kb) is slightly higher than the average calculated for the complete human genome (one gene per 90 kb). The comparison of the number and distribution of repetitive elements shows that the proportion of human DNA made up by interspersed repeats (43.8%) is significantly higher than in the corresponding mouse DNA (30.1%). This partly explains why the human DNA is longer between the landmark genes used to define the orthologous positions in human and mouse.

Mapping protein matrix cavities in human cytoglobin through Xe atom binding: a crystallographic investigation

Cytoglobin is the fourth recognized globin type, almost ubiquitously distributed in human tissues; its function is still poorly understood. Cytoglobin displays a core region of about 150 residues, structurally related to hemoglobin and myoglobin, and two extra segments, about 20 residues each, at the N- and C-termini. The core region hosts a large apolar cavity, held to provide a ligand diffusion pathway to/from the heme, and/or ligand temporary docking sites. Here we report the crystal structure (2.4A resolution, R-factor 19.1%) of a human cytoglobin mutant bearing the CysB2(38) --> Ser and CysE9(83) --> Ser substitutions (CYGB*), treated under pressurized xenon. Three Xe atoms bind to the heme distal site region of CYGB* mapping the protein matrix apolar cavity. Despite the conserved globin fold, the cavity found in CYGB* is structured differently from those recognized to play a functional role in myoglobin, neuroglobin, truncated hemoglobins, and Cerebratulus lacteus mini-hemoglobin.

Instability of Tandem Repetitive DNA in “Natural” and Transgenic Organisms

Genome research of the last 10 years has forced us to re-evaluate our view of DNA as a relatively stable molecule. Unprecedented levels of DNA instability in germline and soma cells have been observed, associated primarily with tandem repetitive (tr) DNA sequences. We will discuss here briefly the structure and possible functions of trDNA in eukaryotes, the putative mechanisms of mutational change in repeat clusters and the evolutionary dimensions of trDNA instability (for other relevant reviews, sec Pardue and Hennig 1990; Vogt 1990; Charlesworth et al. 1994). A special focus will be on the behaviour of trDNA after DNA transfer experiments in transgenic organisms, with reference to our own work in dipteran insects.