OrganismsDiseasesPhenomena and Processes
SpalaxMole RatsMitochondrial DynamicsRodentiaAnoxiaDisease Resistance
Spalax
A genus of blind, subterranean MOLE RATS, in the subfamily Spalacidae, family MURIDAE, used as a animal model in neurophysiology. There are at least five different species described, all found in the Ukraine.
Mole Rats
Any of several burrowing rodents of the families MURIDAE and Bathyergidae, found in eastern Europe, Africa, and Asia. They have short limbs, small eyes with permanently closed lids, and no tail. Three genera SPALAX (Muridae), Heterocephalus (Bathyergidae) and Cryptomys (Bathyergidae) are used frequently as experimental animals in biomedical research. (From Walker's Mammals of the World, 6th ed)
Mitochondrial Dynamics
The continuous remodeling of MITOCHONDRIA shape by fission and fusion in response to physiological conditions.
Rodentia
A mammalian order which consists of 29 families and many genera.
Anoxia
Relatively complete absence of oxygen in one or more tissues.
Disease Resistance
The capacity of an organism to defend itself against pathological processes or the agents of those processes. This most often involves innate immunity whereby the organism responds to pathogens in a generic way. The term disease resistance is used most frequently when referring to plants.

p53--a key player in tumoral and evolutionary adaptation: a lesson from the Israeli blind subterranean mole rat. (1/23)

p53 is a transcription factor involved in maintaining genomic integrity by regulating genes involved in cell cycle arrest, DNA repair, and programmed cell death. Various post transcriptional modifications result in activated p53 with varying binding affinity to its targets. The other members of the p53 family (p63, p73) and associated proteins also contribute to the specificity of gene activation resulting in the final cell responses. p53 is commonly mutated in human cancer and is activated by diverse cellular events, including hypoxia. Many sources of genetic diversity, including random or stress-related mutagenesis, affect normal species evolution. The blind subterranean mole rat lives in sealed underground tunnels, subjected to routine hypoxia due to abrupt and sharp changes in O2 supply. We cloned the mole rat's p53 gene and identified two amino acid substitutions in its binding domain, in the same positions that are mutated in cancer. These substitutions lead to increased p53 activation of DNA-repair elements and reduced activation of apoptotic genes. We propose that sequence-specific changes in the mole rat's p53 gene provide an example of how transcription factors that regulate many genes can also account for rapid and broad phenotypic diversity by altering the binding affinity to individual target genes.  (+info)

Adaptive evolution of heparanase in hypoxia-tolerant Spalax: gene cloning and identification of a unique splice variant. (2/23)

Heparan sulfate (HS) side chains of HS proteoglycans bind to and assemble extracellular matrix proteins and play important roles in cell-cell and cell-extracellular matrix interactions. HS chains bind a multitude of bioactive molecules and thereby function in the control of multiple normal and pathological processes. Enzymatic degradation of HS by heparanase, a mammalian endoglycosidase, affects the integrity and functional state of tissues and is involved in, among other processes, inflammation, angiogenesis, and cancer metastasis. Here, we report the cloning of heparanase from four Israeli species of the blind subterranean mole rat (Spalax ehrenbergi superspecies), 85% homologous to the human enzyme. Unlike its limited expression in human tissues, heparanase is highly expressed in diverse Spalax tissues. Moreover, we have identified a unique splice variant of the Spalax enzyme lacking 16 aa encoded by exon 7. This deletion resulted in a major defect in trafficking and processing of the heparanase protein, leading to a loss of its enzymatic activity. Interspecies variation was noted in the sequence and in the expression of the splice variant of the heparanase gene in blind mole rats living under different ecogeographical stresses, indicating a possible role in adaptation to stress in Spalax evolution.  (+info)

Evolutionary regulation of the blind subterranean mole rat, Spalax, revealed by genome-wide gene expression. (3/23)

We applied genome-wide gene expression analysis to the evolutionary processes of adaptive speciation of the Israeli blind subterranean mole rats of the Spalax ehrenbergi superspecies. The four Israeli allospecies climatically and adaptively radiated into the cooler, mesic northern domain (N) and warmer, xeric southern domain (S). The kidney and brain mRNAs of two N and two S animals were examined through cross-species hybridizations with two types of Affymetrix arrays (mouse and rat) and muscle mRNA of six N and six S animals with spotted cDNA mouse arrays. The initial microarray analysis was hypothesis-free, i.e., conducted without reference to the origin of animals. Principal component analysis revealed that 20-30% of the expression signal variability could be explained by the differentiation of N-S species. Similar N-S effects were obtained for all tissues and types of arrays: two Affymetrix microarrays using probe oligomer signals and the spotted array. Likewise, ANOVA and t test statistics demonstrated significant N-S ecogeographic divergence and region-tissue specificity in gene expression. Analysis of differential gene expression between species corroborates previous results deduced by allozymes and DNA molecular polymorphisms. Functional categories show significant N-S ecologic putative adaptive divergent up-regulation of genes highlighting a higher metabolism in N, and potential adaptive brain activity and kidney urine cycle pathways in S. The present results confirm ecologic-genomic separation of blind mole rats into N and S. Gene expression regulation appears to be central to the evolution of blind mole rats.  (+info)

Differential expression profiling of the blind subterranean mole rat Spalax ehrenbergi superspecies: bioprospecting for hypoxia tolerance. (4/23)

The blind subterranean mole rat of the Spalax ehrenbergi superspecies, living underground and exposed to fluctuating oxygen and carbon dioxide levels, is an excellent model of hypoxic tolerance. Unique structural and functional adaptations of the cardiovascular and respiratory systems allow these underground mammals to survive at severely reduced oxygen tension. Elucidation of the natural variation and evolutionary changes under hypoxia within this superspecies may have biomedical applications in ischemic syndromes and cancer. In this study, we have compared expression profiles of muscle tissue at normoxic (21%) and hypoxic (3%) levels of oxygen concentration between two allospecies of the S. ehrenbergi superspecies exhibiting differential hypoxia tolerance in accordance with their ecological regimes. Profiling was performed by cross-species hybridization using a mouse cDNA array containing 15,000 gene elements. Results uncover species-specific responses to hypoxic stress among numerous genes involved in angiogenesis, apoptosis, and oxidative stress management. Among the most striking results are differential expressions of cardiac ankyrin repeat protein (Carp), activating transcription factor 3 (Atf3), LIM and cysteine-rich domains 1 (Lmcd1), cysteine and glycine-rich protein 2 (Csrp2), and ras homolog gene family, member B (RhoB). These findings support the hypothesis that allospecies of the S. ehrenbergi superspecies are variably adapted to fluctuating oxygen tension. Differences may involve specific metabolic pathways and functional adaptations at the structural and molecular levels.  (+info)

Tissue-specific activity of the blind mole rat and the two nucleotide-mutated mouse alphaB-crystallin promoter in transgenic mice. (5/23)

The alphaB-crystallin and HspB2 genes are located approximately 0.9 kb apart in a head-to-head arrangement in mammals. Previous experiments have shown that a truncated -668/+45 alphaB-crystallin enhancer/promoter fragment from blind mole rats (Spalax ehrenbergi), which have nonfunctional lenses, lacks lens activity and has enhanced muscle activity in transgenic mice. Here we show that the full-length mole rat alphaB-crystallin intergenic region behaves similarly in transgenic mice. A two-nucleotide mutation ((-273)CA-->G) in the mouse alphaB-crystallin enhancer/promoter fragment mimicking the wild-type mole rat sequence functionally converted the mouse promoter fragment to that of the wild-type mole rat promoter when tested in transgenic mice. The reciprocal mutation in the mole rat promoter fragment ((-272)G-->CA) did not affect its activity. Oligonucleotides from the wild-type mouse and mole rat alphaB-crystallin promoter region under study formed distinct complexes with nuclear proteins from cultured cells. The mouse mutant sequence lost binding ability, whereas the mutated mole rat sequence gained the ability to form a complex similar in size to that of the wild-type mouse oligonucleotide. Our data support the idea that blind mole rats' alphaB-crystallin promoter activity was modified during the evolution of subterranean life and shows that tissue-specific promoter activity can be modulated by changing as few as two apparently neutral nucleotides in the mouse alphaB-crystallin enhancer region, implying the importance of the context of regulatory sequences for promoter activity.  (+info)

An extracellular region of the erythropoietin receptor of the subterranean blind mole rat Spalax enhances receptor maturation. (6/23)

Erythropoietic functions of erythropoietin (EPO) are mediated by its receptor (EPO-R), which is present on the cell surface of erythroid progenitors and induced by hypoxia. We focused on EPO-R from Spalax galili (sEPO-R), one of the four Israeli species of the subterranean blind mole rat, Spalax ehrenbergi superspecies, as a special natural animal model of high tolerance to hypoxia. Led by the intriguing observation that most of the mouse EPO-R (mEPO-R) is retained in the endoplasmic reticulum (ER), we hypothesized that sEPO-R is expressed at higher levels on the cell surface, thus maximizing the response to elevated EPO, which has been reported in this species. Indeed, we found increased cell-surface levels of sEPO-R as compared with mEPO-R by using flow cytometry analysis of BOSC cells transiently expressing HA-tagged EPO-Rs (full length or truncated). We then postulated that unique extracellular sEPO-R sequence features contribute to its processing and cell-surface expression. To map these domains of the sEPO-R that augment receptor maturation, we generated EPO-R derivatives in which parts of the extracellular region of mEPO-R were replaced with the corresponding fragments of sEPO-R. We found that an extracellular portion of sEPO-R, harboring the N-glycosylation site, conferred enhanced maturation and increased transport to the cell surface of the respective chimeric receptor. Taken together, we demonstrate higher surface expression of sEPO-R, attributed at least in part to increased ER exit, mediated by an extracellular region of this receptor. We speculate that these sEPO-R sequence features play a role in the adaptation of Spalax to extreme hypoxia.  (+info)

Urodele p53 tolerates amino acid changes found in p53 variants linked to human cancer. (7/23)

BACKGROUND: Urodele amphibians like the axolotl are unique among vertebrates in their ability to regenerate and their resistance to develop cancers. It is unknown whether these traits are linked at the molecular level. RESULTS: Blocking p53 signaling in axolotls using the p53 inhibitor, pifithrin-alpha, inhibited limb regeneration and the expression of p53 target genes such as Mdm2 and Gadd45, suggesting a link between tumor suppression and regeneration. To understand this relationship we cloned the p53 gene from axolotl. When comparing its sequence with p53 from other organisms, and more specifically human we observed multiple amino acids changes found in human tumors. Phylogenetic analysis of p53 protein sequences from various species is in general agreement with standard vertebrate phylogeny; however, both mice-like rodents and teleost fishes are fast evolving. This leads to long branch attraction resulting in an artefactual basal emergence of these groups in the phylogenetic tree. It is tempting to assume a correlation between certain life style traits (e.g. lifespan) and the evolutionary rate of the corresponding p53 sequences. Functional assays of the axolotl p53 in human or axolotl cells using p53 promoter reporters demonstrated a temperature sensitivity (ts), which was further confirmed by performing colony assays at 37 degrees C. In addition, axolotl p53 was capable of efficient transactivation at the Hmd2 promoter but has moderate activity at the p21 promoter. Endogenous axolotl p53 was activated following UV irradiation (100 j/m2) or treatment with an alkylating agent as measured using serine 15 phosphorylation and the expression of the endogenous p53 target Gadd45. CONCLUSION: Urodele p53 may play a role in regeneration and has evolved to contain multiple amino acid changes predicted to render the human protein defective in tumor suppression. Some of these mutations were probably selected to maintain p53 activity at low temperature. However, other significant changes in the axolotl proteins may play more subtle roles on p53 functions, including DNA binding and promoter specificity and could represent useful adaptations to ensure p53 activity and tumor suppression in animals able to regenerate or subject to large variations in oxygen levels or temperature.  (+info)

Exploration and navigation in the blind mole rat (Spalax ehrenbergi): global calibration as a primer of spatial representation. (8/23)

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Spalax is a genus of subterranean rodents, also known as mole rats, that are characterized by their blindness, lack of external ears, and highly specialized social structure and lifestyle. They primarily dwell in underground burrows and are found in Eastern Europe and Central Asia.

"Spalax" is a genus of subterranean rodents, also known as mole rats, that are found primarily in Eastern and Southeastern Europe and Western Asia. They are characterized by their blindness, lack of external ears, and highly specialized digging abilities. While "Spalax" is not a medical term per se, it is sometimes used in scientific research to refer to this specific genus of animals. Some studies have investigated the unique physiology and genetics of Spalax species, including their resistance to cancer and hypoxia, which may have implications for human medicine.

*Mole rats*, specifically the naked mole-rat (*Heterocephalus glaber*), are subterranean rodents known for their eusocial behavior, longevity, and resistance to cancer and oxidative stress, making them a valuable model in biomedical research.

A mole rat is not a medical term, but a common name for a burrowing rodent that belongs to the family Bathyergidae. There are about 20 species of mole rats, also known as "blind mole rats" or "naked mole rats," depending on the region and scientific classification.

Mole rats are fascinating creatures with several unique biological features. They are primarily subterranean animals, living in complex tunnel systems that they dig with their powerful incisors and sharp claws. Mole rats have reduced eyes or are completely blind, relying instead on their highly developed senses of touch and smell to navigate their environment.

One species, the naked mole rat (Heterocephalus glaber), is particularly well-known for its unusual biology and social behavior. Naked mole rats live in large colonies with a single breeding female (the queen) and multiple males. The queen is the only reproductively active female, while the other members of the colony function as workers, caring for the young and maintaining the burrow system.

Naked mole rats have several remarkable biological traits, including an extraordinarily long lifespan for a rodent (up to 30 years or more) and resistance to cancer. They are also able to survive in low-oxygen environments and exhibit a unique form of social behavior called eusociality, similar to that seen in bees and ants.

While mole rats may not have a direct medical definition, their unique biology has attracted significant scientific interest, leading to important discoveries in fields such as aging, cancer research, and neurobiology.

'Mitochondrial dynamics' refer to the processes involving continuous fusion, fission, and movement of mitochondria, which are crucial for maintaining their morphology, distribution, and function within eukaryotic cells.

Mitochondrial dynamics refer to the processes that regulate the shape, size, distribution, and quality control of mitochondria within cells. These dynamic processes include:

1. Mitochondrial Fusion: This is the process by which two adjacent mitochondria merge together to form a single, elongated organelle. Fusion allows for the exchange of mitochondrial content, including DNA, proteins, and metabolites, which helps maintain genetic stability and promote bioenergetic efficiency.
2. Mitochondrial Fission: This is the process by which a single mitochondrion divides into two separate organelles. Fission plays a crucial role in mitochondrial division, inheritance, and quality control, as it enables the segregation of damaged or dysfunctional mitochondria for degradation via autophagy (mitophagy).
3. Mitochondrial Transport: This is the active movement of mitochondria within cells, facilitated by cytoskeletal motor proteins. Mitochondrial transport enables organelles to be distributed evenly throughout the cell and to reach specific subcellular locations where their energy demands are high.
4. Mitochondrial Dynamics Regulation: The regulation of mitochondrial dynamics involves a complex interplay between various proteins, lipids, and signaling pathways that control fusion, fission, transport, and quality control processes. These regulatory mechanisms help maintain the balance between mitochondrial biogenesis (the generation of new organelles) and mitophagy (the removal of damaged ones), ensuring proper cellular homeostasis and function.

Dysregulation of mitochondrial dynamics has been implicated in various pathological conditions, including neurodegenerative diseases, metabolic disorders, and aging-related processes.

Rodentia is a large order of small to medium-sized mammals characterized by a single pair of continuously growing incisors in each of the upper and lower jaws, which they use to gnaw materials, and a dental formula that begins with the incisors.

"Rodentia" is not a medical term, but a taxonomic category in biology. It refers to the largest order of mammals, comprising over 40% of all mammal species. Commonly known as rodents, this group includes mice, rats, hamsters, gerbils, guinea pigs, squirrels, prairie dogs, capybaras, beavers, and many others.

While "Rodentia" itself is not a medical term, certain conditions or issues related to rodents can have medical implications. For instance, rodents are known to carry and transmit various diseases that can affect humans, such as hantavirus, leptospirosis, salmonellosis, and lymphocytic choriomeningitis (LCMV). Therefore, understanding the biology and behavior of rodents is important in the context of public health and preventive medicine.

Anoxia is a serious condition characterized by a total absence or extremely low levels of oxygen in the blood, leading to hypoxic damage of tissues and organs, which can potentially result in severe impairment or failure of vital functions if not promptly treated and corrected.

Anoxia is a medical condition that refers to the absence or complete lack of oxygen supply in the body or a specific organ, tissue, or cell. This can lead to serious health consequences, including damage or death of cells and tissues, due to the vital role that oxygen plays in supporting cellular metabolism and energy production.

Anoxia can occur due to various reasons, such as respiratory failure, cardiac arrest, severe blood loss, carbon monoxide poisoning, or high altitude exposure. Prolonged anoxia can result in hypoxic-ischemic encephalopathy, a serious condition that can cause brain damage and long-term neurological impairments.

Medical professionals use various diagnostic tests, such as blood gas analysis, pulse oximetry, and electroencephalography (EEG), to assess oxygen levels in the body and diagnose anoxia. Treatment for anoxia typically involves addressing the underlying cause, providing supplemental oxygen, and supporting vital functions, such as breathing and circulation, to prevent further damage.

"Disease resistance in medical terms refers to the inherent or acquired ability of an organism to withstand or limit the negative effects of pathogens, toxic substances, or environmental stressors, thereby maintaining its health and homeostasis."

Disease resistance, in a medical context, refers to the inherent or acquired ability of an organism to withstand or limit infection by a pathogen, such as bacteria, viruses, fungi, or parasites. This resistance can be due to various factors including the presence of physical barriers (e.g., intact skin), chemical barriers (e.g., stomach acid), and immune responses that recognize and eliminate the pathogen.

Inherited disease resistance is often determined by genetics, where certain genetic variations can make an individual more or less susceptible to a particular infection. For example, some people are naturally resistant to certain diseases due to genetic factors that prevent the pathogen from infecting their cells or replicating within them.

Acquired disease resistance can occur through exposure to a pathogen, which triggers an immune response that confers immunity or resistance to future infections by the same pathogen. This is the basis of vaccination, where a weakened or dead form of a pathogen is introduced into the body to stimulate an immune response without causing disease.

Overall, disease resistance is an important factor in maintaining health and preventing the spread of infectious diseases.

Blind molSubterraneanRodent1976LabelMolecularFunctionalConeFranceLongEhrenbergiGraecusMole ratsGenusBlindResistanceMusicAnalysis
Blind mol10
  • Prior to 2013, Spalax was widely considered the only member of Spalacinae, with all blind mole-rat species being grouped within it. (wikipedia.org)
  • Old views and new insights: taxonomic revision of the Bukovina blind mole rat, Spalax graecus (Rodentia: Spalacinae)" (PDF). (wikipedia.org)
  • A green cone-like pigment in the 'blind' mole-rat Spalax ehrenbergi: functional expression and photochemical characterization. (ox.ac.uk)
  • The degenerate subcutaneous eye of the blind mole rat belonging to the Spalax ehrenbergi superspecies has been shown to contain a long wavelength sensitive (LWS) cone pigment. (ox.ac.uk)
  • Adaptive loss of ultraviolet-sensitive/violet-sensitive (UVS/VS) cone opsin in the blind mole rat (Spalax ehrenbergi). (ox.ac.uk)
  • In previous studies, fully functional rod and long-wavelength-sensitive (LWS) cone photopigments have been isolated from the eye of the subterranean blind mole rat (Spalax ehrenbergi superspecies). (ox.ac.uk)
  • abstract = "The occipital cortex of the naturally blind mole rat, Spalax ehrenbergi, is occupied by an area of somatosensory representation. (haifa.ac.il)
  • Rehkämper, G, Necker, R & Nevo, E 1994, ' Functional anatomy of the thalamus in the blind mole rat Spalax ehrenbergi: An architectonic and electrophysiologically controlled tracing study ', Journal of Comparative Neurology , vol. 347, no. 4, pp. 570-584. (haifa.ac.il)
  • A genomic and transcriptomic study has revealed the genes that allowed the blind mole rat (Spalax galili) to adapt to the stresses of life underground and provides clues as to how it resists cancer. (oncologynurseadvisor.com)
  • Dear Madam/Sir We are looking for independent, dedicated Bioinformaticians as post-doctorate fellows for a project aimed at revealing the mechanisms of cancer-resistance and anti-cancer activity of the hypoxia-tolerant subterranean, blind mole-rat, Spalax (if you wish to have a clue you can watch the links down in my signature. (ubc.ca)
Subterranean1
  • The possible relevance of these findings for the evolutionary adaptation of Spalax to a subterranean ecotope is discussed. (ox.ac.uk)
Rodent3
  • Spalax is a genus of rodent in the family Spalacidae, subfamily Spalacinae (blind mole-rats). (wikipedia.org)
  • Also in contrast to the rodent pigments, the Spalax pigment exhibits anion-dependent spectral properties, displaying a 12 nm blue-shift upon substitution of chloride ions by nitrate ions. (ox.ac.uk)
  • He does not tell us whether Aristotle's animal is the insectivorous Talpa or the rodent mole-rat (Spalax typhus). (google.nl)
19761
  • Reedición de un homenaje a Gottsching que incluye dos largos temas del músico grabados en los setenta remezclados y versioneados por Joe Claussell (Deeper Distance, y Ain´t No time for Tears), que le da una perspectiva cercana al techno trancé cósmico y atmosférico, el tercer tema de más de diez minutos es una versión del propio Manuel Göttsching de uno grabado en una actuación en Paris en 1976 (Schuttlecock). (rotordiscos.com)
Label1
Molecular1
  • Using immunocytochemistry and molecular approaches we demonstrate that Spalax is a LWS monochromat. (ox.ac.uk)
Functional1
  • Spalax lacks a functional UVS/VS cone photopigment due to the accumulation of several deleterious mutational changes that have rendered the gene nonfunctional. (ox.ac.uk)
Cone1
  • The absorbance spectrum of the Spalax pigment is strongly red-shifted relative to the very homologous mouse, rabbit and rat green cone pigments (508-510 nm). (ox.ac.uk)
France1
  • Later on, when reissued on CD, The Laser's Edge issued it in '92 with the diecut cover, and in '95, Spalax in France issued it without the diecut. (progarchives.com)
Long1
  • Now the teeth of the Spalax are long, conspicuous, and chisel-shaped, and may well be called xavλióCOPTES. (google.nl)
Ehrenbergi2
  • Evolution under severely stressful conditions has endowed the Middle Eastern subterranean blind mole rat (Spalax ehrenbergi) with unusual longevity, hypoxia tolerance, and cancer resistance, with spontaneous tumor formation never observed. (stemcellsportal.com)
  • Adaptive features of skeletal muscles of mole rats (Spalax ehrenbergi) to intensive activity under subterranean hypoxic conditions. (stemcellsportal.com)
Graecus1
  • Old views and new insights: taxonomic revision of the Bukovina blind mole rat, Spalax graecus (Rodentia: Spalacinae)" (PDF). (wikipedia.org)
Mole rats1
  • Spalax is a genus of rodent in the family Spalacidae, subfamily Spalacinae (blind mole-rats). (wikipedia.org)
Genus1
  • These species were reclassified into the genus Nannospalax, making Spalax one of two extant spalacine genera. (wikipedia.org)
Blind3
  • Prior to 2013, Spalax was widely considered the only member of Spalacinae, with all blind mole-rat species being grouped within it. (wikipedia.org)
  • A Nature Communications study looked at the genetics of adaptation to stressful conditions by the blind mole rat, Spalax galili , which lives underground in low-light, low-oxygen, and high-carbon dioxide environments. (genomeweb.com)
  • Adipose-Derived Stem Cells of Blind Mole Rat Spalax Exhibit Reduced Homing Ability: Molecular Mechanisms and Potential Role in Cancer Suppression. (stemcellsportal.com)
Resistance1
  • Excitingly, the authors discovered that a notable lack of ASC migration towards tumor cells and associated poor intratumoral angiogenesis contributed to cancer resistance in Spalax [3]. (stemcellsportal.com)
Music1
Analysis1
  • Of note, while rat ASCs migrated towards fibrosarcoma cells derived from Spalax, Spalax ASCs displayed no such migrational capacity, suggesting that species-specific differences did not affect the migrational analysis. (stemcellsportal.com)

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