A.C.B. Peters

Somatic pairing of chromosome 1 centromeres in interphase nuclei of human cerebellum

SummaryInterphase nuclei isolated from paraffin-embedded tissue of four normal brains were hybridized with biotinated repetitive DNA probes specific for the (peri) centromeric regions of chromosomes 1 and 7. Hybridization results were visualized with a peroxidase-DAB system after which the number of specific signals per nucleus was counted using bright field microscopy. Using the probe specific for chromosome 7 (p7t1), both the cerebral and the cerebellar samples showed 2 spots in 82% and 83%, respectively, of the nuclei. In situ hybridization with the chromosome 1 probe (pUC1. 77) showed two spots in 69% of the cerebral nuclei. In cerebellar samples, hybridization with pUC1.77 resulted in only one large spot per nucleus in 82% of the cells. The average spot size in nuclei with one signal was about 1.6 times as large as that in nuclei with two signals. These observations suggest that the single large spot in the cerebellar cells is not the result of monosomy of chromosome 1 but that it reflects somatic pairing of the two chromosome 1 centromeres. Based on the size and the fraction of nuclei with one large spot, the small granular neuron is the most likely candidate. The difference between cerebral and cerebellar samples indicates that this somatic pairing of chromosome 1 is a cell-type-dependent phenomenon.

Interphase cytogenetics reveals somatic pairing of chromosome 17 centromeres in normal human brain tissue, but no trisomy 7 or sex-chromosome loss

Nuclei isolated from normal human brain tissue, collected from six autopsies, were hybridized with a panel of nine satellite DNA probes specific for the centromeric regions of chromosomes 1, 6, 7, 10, 11, 17, 18, and the X and Y chromosomes. The results did not confirm the recently reported trisomy 7 and loss of sex chromosomes observed in metaphases obtained from normal brain tissue after short-term cultures; however, cells of all six brains displayed somatic pairing of the chromosome 17 centromeres in approximately 50% of the nuclei.

Feasibility of in situ hybridisation with chromosome specific DNA probes on paraffin wax embedded tissue.

The feasibility was studied of in situ hybridisation using chromosome specific DNA probes on paraffin wax embedded normal and malignant tissues from different organs. Both isolated nuclei and 5 microns sections were used in in situ hybridisation experiments with biotinylated repetitive DNA probes specific for the centromeric regions of chromosomes 1 and 17. The hybridisation results were visualised with peroxidase-diaminobenzidine. The optimal pretreatments with sodium thiocyanate and pepsin were experimentally defined for the different tissues. Although interphase cytogenetics on paraffin wax embedded tissue is possible, the results indicate that it has its limitations, compared with investigations on fresh tumour tissue.

Polymerase chain reaction and viral culture techniques to detect HSV in small volumes of cerebrospinal fluid; an experimental mouse encephalitis study

A technique is described for the detection of HSV-DNA in very small volumes (5-10 microliters) of cerebrospinal fluid (CSF). The method was evaluated in CSF samples of 4-6-week-old mice inoculated with HSV-1 via the corneal route. The sensitivity of the PCR assay was compared with results of spin-amplified viral culture with immunofluorescent visualization (SAC/IF), routine viral culture (RVC) and radioactive dot-blot hybridization (DBA) in CSF samples obtained from other mice. The results show the PCR to be superior over the other techniques: infectious virus or viral DNA in CSF was demonstrated by PCR, SAC/IF, RVC and DBA in 68, 55, 20 and 2.5%, respectively. These results show the feasibility of the PCR for a rapid, non-invasive diagnosis of human HSV-encephalitis.

Diagnosis of progressive multifocal leucoencephalopathy by hybridisation techniques.

In situ hybridisation with acetyl-aminofluorene (AAF) and 35S-labelled DNA probes for polyomaviruses, was used to detect JC virus DNA in brain necropsy material in a patient with progressive multifocal leucoencephalopathy (PML). In a second patient PML was diagnosed from a brain necropsy specimen using the same technique. The main infected cell type were oligodendrocytes; dot hybridisation was used to estimate the number of viral copies in each infected cell. Southern blot hybridisation for further analysis of the viral genome was also carried out. In situ hybridisation with non-radioactive labelled polyomavirus DNA provides a simple and specific means for studying viral DNA in formaldehyde fixed tissue sections from patients with suspected PML. Even in small biopsy samples hybridisation results can be correlated with standard histopathological, immunocytochemical, and electron microscopic findings.

Spread of herpes simplex virus to the cerebrospinal fluid and the meninges in experimental mouse encephalitis

SummaryThe development of the inflammatory response within the brain, meninges and cerebrospinal fluid (CSF) compartment has been studied for the first time simultaneously in experimental herpes simplex virus (HSV) encephalitis after inoculation via the cornea. Two major viral pathways were found from the eye to the brain: one through the trigeminal nerve to the brain stem and one through the nasolacrimal duct to the olfactory system. Viral antigen was found to be present in the CNS before there were clinical signs or cellular infiltration of brain tissue. Subsequently, the virus spread to all parts of the trigeminal brain stem complex. This phenomenon was accompanied by severe inflammation of the meninges covering the trigeminal root near its entry into the brain stem. The meninges near the entry of the olfactory fila also contained antigen. However, HSV-1 did not spread along meningeal rami of the trigeminal nerve and, consequently, is — at least in this experimental model — not a route to reach the inferior frontal and temporal lobes. The development of CSF changes followed the histopathological development of meningitis and encephalitis closely. HSV-DNA could be detected in the CSF from day 4 post inoculation (p.i.) and HSV-1-specific immunofluorescence in CSF cells was convincingly present on day 5 p.i.; on the same days (4 and 5 p.i.) inflammatory cells were found in apposition to infected cells in the brain. We postulate that HSV is carried to the CSF by infected leukocytes rather than a direct spread to the CSF by simple extension of the encephalitic process to the meningeal surface. Consequently, the chances of detection of viral antigen in CSF cells or HSV-DNA by polymerase chain reaction in CSF at an early, pre-encephalitic stage of disease are slight. The relevance of the findings to the pathogenesis and diagnosis of human herpes simplex encephalitis is discussed.

Polymerase Chain Reaction Detection of Herpes Simplex Virus in Cerebrospinal Fluid

Herpes simplex encephalitis (HSE) is a serious disease with significant morbidity and mortality if left untreated. It can be treated with acyclovir, but for this to be effective it must be instituted early during the course of disease. Noninvasive, early diagnosis, however, is presumptive at best, and many patients are treated without a definitive diagnosis.

Interphase cytogenetic analysis of gliomas.

Interphase cytogenetics is the application of nonradioactive in situ hybridization with chromosome-specific DNA probes to interphase nuclei. The possibilities and limitations of this new technique for the study of chromosomal aberrations in gliomas are discussed.

Interphase cytogenetics on brain tumors

The development and application of a procedure for interphase cytogenetics on brain tumor material is described. Nuclei isolated from freshly removed brain tumor tissue were investigated for chromosomal aberrations by nonradioactive in situ hybridization with a panel of chromosome-specific probes. The panel consisted of nine satellite DNA probes specific for the centromeric regions of chromosomes 1, 6, 7, 10, 11, 17, 18, X, and Y. For each probe, the number of hybridization signals per cell was determined in 200 nuclei. It was inferred from the hybridization results that in 11 gliomas (seven astrocytomas grade II-IV, three oligodendrogliomas, and one ependymoma) the numerical aberrations were gains of chromosomes 1 (once), 7 (twice), 10 (once), 11 (twice), and X (twice); losses of chromosomes 1 (once), 10 (twice), 17 (twice), and Y (once); and complete tetraploidy (once). Among the 18 investigated meningiomas monosomy 18 and trisomy 17 were observed once and twice, respectively. An additional hybridization with a cosmid probe for the BCR gene on 22q11 indicated monosomy 22q in 11 meningiomas. These results show the value of interphase cytogenetics for the analysis of solid tumors for which it is relatively difficult to obtain sufficient metaphases of good quality for conventional cytogenetics.

Coxsackie B meningitis; diagnostic problems

Rapid diagnosis of viral meningitis can be performed by immunofluorescence of cerebrospinal fluid (c.s.f. cells). The c.s.f, cells are sedimented in a Sayk chamber in order to obtain morphologically well preserved cells. Generally 3 to 4 slides can be made from the c.s.f, o f one puncture. The first slide is stained by the indirect method with a mixture of antisera against the prevailing enteroviruses. If fluorescence is postive, further slides are stained with serum pools against Coxsackie A, Coxsackie B and E.C.H.O., respectively, to determined the nature of the virus. This rapid diagnosis had to be confirmed by isolation of the agent and by serological reactions. The cases presented here were selcted because of the failure to isolate the virus from the cerebrospinal fluid, throat swab and faeces. The complement fixation test with a genetron-extracted antigen pool of the six Coxsackie B viruses proved to be positive, All sera showed high titres in both first and second sample, except in one case which showed a significant rise in titre. The results of the microneutralization test were more conclusive. This test is performed in microtitre tissue culture plates using Vero cells in Eagles M.E.M. with 5 % fetal calf serum and incubated in a CO2 incubator. The serum dilution was tested against 100 TCID 50 and the neutralization end point was determined according to the Reed and Munch method. In all cases in which the complement fixation test did not show a further increase in titre the neutralization test still did and confirmed the immnnofluorescence diagnosis of the c.s.f, cells.