Failure to infect laboratory rodent hosts with human isolates of Rodentolepis (= Hymenolepis) nana

Confusion exists over the species status and host-specificity of the tapeworm Rodentolepis (= Hymenolepis) nana. It has been described as one species, R. nana, found in both humans and rodents. Others have identified a subspecies; R. nana var. fraterna, describing it as morphologically identical to the human form but only found in rodents. The species present in Australian communities has never been identified with certainty. Fifty one human isolates of Rodentolepis (= Hymenolepis) nana were orally inoculated into Swiss Q, BALB/c, A/J, CBA/ CAH and nude (hypothymic) BALB/c mice, Fischer 344 and Wistar rats and specific pathogen free (SPF) hamsters. Twenty four human isolates of R. nana were cross-tested in flour beetles, Tribolium confusum. No adult worms were obtained from mice, rats or hamsters, even when immunosuppressed with cortisone acetate. Only one of the 24 samples developed to the cysticercoid stage in T. confusum; however, when inoculated into laboratory mice the cysticercoids failed to develop into adult worms. The large sample size used in this study, and the range of techniques employed for extraction and preparation of eggs provide a comprehensive test of the hypothesis that the human strain of R. nana is essentially non-infective to rodents.     

A cytogenetic study of the Caspian pony

The group of Caspian ponies studied contained some animals with 65 chromosomes and others with 64 chromosomes. The morphology and G-banding pattern of the chromosomes resembled those of Equus caballus and E. przewalskii. The karyogram of animals with 65 chromosomes was identical to that of the cross between E. caballus and E. przewalskii. It is suggested that the Caspian pony is the product of natural hybridization between E. caballus and E. prezwalskii. Low reproductive effeciency of the Caspian pony is suggested as the cause of decline in the population of these animals.     

A cytogenetic study of recurrent abortion

Summary Chromosomal analysis was performed in a series of 27 women with repeated spontaneous abortions and in 16 of the husbands. In one woman a balanced translocation of the type 13q/15q was detected, and a pericentric inversion of a chromosome A₁ was found in the husband of another proband. The significance of these findings is discussed.

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Zusammenfassung Bei 27 Frauen mit wiederholten Aborten und bei 16 zugehörigen Ehemännern wurden Chromosomenanalysen durchgeführt. Bei einer Probandin fand sich eine balancierte Translokation 13q/15q, bei dem Ehemann einer anderen Probandin eine perizentrische Inversion eines Chromosoms A₁. Die Bedeutung der Befunde wird diskutiert.

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The study was supported by the Deutsche Forschungsgemeinschaft, Sonderforschungsbereich 35.     

五种紫萁属植物的细胞遗传学研究

对紫萁属Osmunda五种植物:狭叶紫萁D angustifolia Ching、紫萁O japonica Thunb.、华南紫萁O vachellii Hook.、粗齿紫萁O banksifolia(Presl)Kuhn和粤紫萁O.mildei C.Chr.的体细胞染色体形态和孢子母细胞减数分裂时染色体的行为进行了研究.五种紫其属植物的体细胞染色体数目均为2n=44,孢子母细胞减数分裂过程中,狭叶紫萁,紫萁、华南紫萁和粗齿紫萁染色体配对和联合行为正常,中期I染色体构型多为环状二价体,粗齿紫萁偶尔可观察到三价体和单价体,狭叶紫萁中期I偶可观察到1-2个提早分离的单价体,后期II可观察到染色体桥和断片,据此推测易位和倒位等染色体畸变作用在紫萁属植物物种形成和演化过程中具有重要意义.粤紫萁是华南分布的一个特有珍稀种、孢子母细胞减数分裂前期到中期无染色体配对和联会,导致染色体后期行为异常,80%的孢子母细胞有落后染色体和不均等分离现象,形成的孢子几乎完全败育,基于粤紫萁减数分裂显著偏离正常的同源染色体配对和联会现象,结合核型方面和形态学方面证据,认为粤紫萁是一个杂交种.     

A cytogenetic study of repeated spontaneous abortions.

During a cytogenetic study of spontaneous abortions, successive abortions from 40 couples were karyotyped. The chromosome constitutions of the first and second abortions were found to be highly correlated. In each of 21 instances in which the first abortion was chromosomally normal, the subsequent abortion(s) was normal as well. In nine cases, the two abortions were chromosomally abnormal, and in four of these, both abortions were trisomic. Combined with findings from other studies of consecutive spontaneous abortions, the present data indicate that certain couples are at an increased risk for either repeated chromosomally normal abortions or for repeated trisomic conceptions. The increased risk of trisomy does not seem to be restricted to a particular chromosome, and the magnitude of the risk increase appears to be independent of maternal age.     

A molecular cytogenetic study of chromosome evolution in chimpanzee

We applied multitude multicolor banding (mMCB) in combination with a novel FISH DNA probe set including subcentromeric, subtelomeric and whole chromosome painting probes (subCTM) to characterize a Pan paniscus (PPA) cell line. These powerful techniques allowed us to refine the breakpoints of a pericentric inversion on chimpanzee chromosome 4, and discovered a novel cryptic pericentric inversion in chimpanzee chromosome 11. mMCB provided a starting point for mapping and high resolution analysis of breakpoints on PPA chromosome 4, which are within a long terminal repeat (LTR) and surrounded by segmental duplications, as well as the integration/expansion sites of the interstitial heterochromatin on chimpanzee chromosomes 6 and 14. Moreover, we found evidence at hand for different types of heterochromatin in the chimpanzee genome. Finally, shedding new light on the human/chimpanzee speciation, karyotypes of three members of the genus Pan were studied by mMCB and no cytogenetic differences were found although the phylogenetic distance between these subspecies is suggested to be 2.5 million years.     

A cytogenetic study on congenital limb malformations in the Japanese monkey (Macaca fuscata)

A cytogenetic investigation was performed on 88 Japanese monkeys (Macaca fuscata) with abnormal limbs from 11 free-ranging provisioned troops including nine individuals with abnormalities indistinguishable as to whether they were congenital or injurious. All of the monkeys with abnormal limbs including the nine questionable individuals had the same karyotypes as those of normal individuals. The chromosome number was 42, consisting of 20 bi-arm autosome pairs and a submetacentric X-chromosome and Y-chromosome. The ninth chromosome pair, which was the only chromosome pair with remarkable secondary constriction, displayed length polymorphism of the centromeric C-band and secondary constriction in both deformed and normal monkeys. These kinds of variants have also been commonly found in other monkey species, which have almost the same karyotype as the Japanese monkey and have not been reported to show frequent occurrence of limb malformation. We concluded therefore that chromosomal abnormalities could be excluded from the main causal factors for limb malformations of the Japanese monkey.     

The cytogenetic consequences of chronic irradiation in rodent populations inhabiting the Eastern Urals Radioactive Trace zone

In bone marrow cells of rodents (Apodemus (Sylvaemus) uralensis Pall., 1811, Apodemus agrarius Pall., 1771) inhabiting the Eastern Urals Radioactive Trace (EURT) zone (Kyshtym radiation accident 1957) and adjacent areas of Urals, the chromosome instability and 90Sr accumulation in bones were investigated. Intensive mutagenic process in both species from impact plots (the soil pollution by 90Sr 2322-16690 kBq/m2) was found. Significant positive correlation of aberrant cells frequencies and 90Sr was shown. Possible causes of the lack of resistance to long-term mutagenic factor (over 100 generations since 50 years from the accident) such as migration of animals and specific configuration of the EURT zone (narrow extended territory with sharply falling gradient of radionuclide pollution), which considerably decrease the probability that certain changes will be fixed and inherited in a series of generations of rodents, are discussed.     

Wolf-Hirschhorn syndrome: A case demonstrated by a cytogenetic study

We present a case with a 4p terminal deletion, evidenced in GTG-banded chromosome study. Phenotypic signs described in the classical Wolf-Hirschhorn syndrome were found on clinical examination of our patient.     

A cytogenetic study of human spontaneous abortions using banding techniques

Summary The karyotypes of 941 singleton and 42 twin abortuses and 4 cystic placentae were determined. 30.5% of the singletons were chromosomally abnormal; 49.8% of these were trisomic, 23.7% X-monosomics and 17.4% polyploid. 143 trisomies were identified by banding; over a third had an extra chromosome 16, more than 10% and extra 21 or 22 and about 5% an extra 2, 18 or 15. Examples of trisomy 3, 4, 8, 9, 10, 13, 14 and 20 were also encountered. Using the data from two other published studies, the prevalence of different trisomies was estimated and an attempt was made to relate the karyotype of the conceptus to its subsequent development.     

A prospective cytogenetic study of 36 cases of DiGeorge syndrome

Cytogenetic analysis was carried out in a prospective series of 36 children with DiGeorge syndrome. High-resolution banding (> 850 bands/haploid set) was achieved in 30 cases. Monosomy 22q11.21-->q11.23 was found in 9 of these 30 cases. In each of these cases monosomy 22q11.21-->q11.23 resulted from an interstitial deletion and not from a translocation. No other chromosome abnormalities were seen.     

A jumping Robertsonian translocation: a molecular and cytogenetic study

We report a patient with mosaicism for two different Robertsonian translocations, both involving chromosome 21. She carries an unbalanced cell line with an i(21q) and a balanced cell line with a rob(21q22q). She is phenotypically normal but has two children who inherited the i(21q) and have Down syndrome. We demonstrate that both abnormal chromosomes are dicentric and that the proband’s 21/21 rearrangement is an isochromosome formed from a maternally derived chromosome 21. We propose a model in which the i(21q) is the progenitor rearrangement in the proband, which subsequently participated in a nonreciprocal rearrangement characteristic of a jumping translocation. In addition, we review other cases of constitutional mosaicism involving jumping translocations. Received: 4 October 1995 / Revised: 14 February 1996     

The cytogenetic evaluation of in vivo genotoxic and cytotoxic activity using rodent somatic cells

With the growing realization that in vitro short-term tests for genotoxicity can never fully mimic in vivo conditions, the evaluation of genotoxic damage in somatic cells of rodents has played an increasingly important role in assessing the carcinogenic potential of suspect compounds. Among the various genotoxic endpoints assessed in in vivo somatic cell assays, cytogenetic endpoints (e.g., chromosomal aberrations, micronuclei, sister chromatid exchanges) continue to be used most frequently. The purpose of this paper is to demonstrate the utility of evaluating different cytogenetic endpoints in the same animal, using as examples studies to evaluate the in vivo genotoxic potential of benzene, of methylisocyanate, and of butadiene, chloroprene and isoprene.Abbreviations CA chromosomal aberrations - MI mitotic index - MIC methylisocyanate - MN-NCE micronucleated monochromatic erythrocytes - MN-PCE micronucleated polychromatic erythrocytes - SCE sister chromatid exchange     

An improved method for cytogenetic analysis of meiotic aneuploidy in rodent and frog spermatocytes

Methods are described for the attachment of isolated spermatocytes to glass slides and the subsequent hypotonic swelling and gradual fixation of the metaphase I and metaphase II cells. The methods minimize cell loss and cell disruption and meiotic metaphase chromosomes become spread within residual cytoplasm thus reducing artefactual chromosome loss. Metaphase II complements from mouse, rat and frog spermatocytes prepared by these procedures had relatively low frequencies of hypoploidy (0.5-1.6%). Bivalent loss was not detected in 916 metaphase I complements. Injection of 0.1 mg/kg demecolcine into mice increased the incidence of metaphase II hypoploidy 8-fold. The hypoploid and hyperploid frequencies here increased equally. The results suggest that the methods described may be useful for the analysis of mechanisms of meiotic aneuploidy including aneuploidy resulting from chromosome loss during meiosis I.     

A primer on rodent identification methods

Identifying laboratory rodents as a group may be sufficient if all the animals are to receive the same treatment and/or manipulation and if individual variations in response are not to be recorded separately. However, it is frequently necessary to be able to differentiate between individual animals used in a study. Identification of individual animals may also be necessary to maintain health records and to properly manage colonies of laboratory animals in compliance with regulatory agencies and research protocol requirements.