Using computer technology to foster learning for understanding.

The literature shows that students typically use either a surface approach to learning, in which the emphasis is on memorization of facts, or a deep approach to learning, in which learning for understanding is the primary focus. This paper describes how computer technology, specifically the use of a multimedia CD-ROM, was integrated into a microbiology curriculum as part of the transition from focusing on facts to fostering learning for understanding. Evaluation of the changes in approaches to learning over the course of the term showed a statistically significant shift in a deep approach to learning, as measured by the Study Process Questionnaire. Additional data collected showed that the use of computer technology supported this shift by providing students with the opportunity to apply what they had learned in class to order tests and interpret the test results in relation to specific patient-focused case studies. The extent of the impact, however, varied among different groups of students in the class. For example, students who were recent high school graduates did not show a statistically significant increase in deep learning scores over the course of the term and did not perform as well in the course. The results also showed that a surface approach to learning was an important aspect of learning for understanding, although only those students who were able to combine a surface with a deep approach to learning were successfully able to learn for understanding. Implications of this finding for the future use of computer technology and learning for understanding are considered.

Cloning of cDNAs of the MLL gene that detect DNA rearrangements and altered RNA transcripts in human leukemic cells with 11q23 translocations.

Recurring chromosomal abnormalities involving translocations at chromosome 11 band q23 are associated with human myeloid and lymphoid leukemia as well as lymphoma. We have identified the gene located at this break-point and have named it MLL (for myeloid-lymphoid, or mixed-lineage, leukemia). The t(4;11), t(6;11), t(9;11), and t(11;19) are among the most common reciprocal translocations in leukemia cells involving this chromosomal band. We now have evidence that the breakpoints in all of these translocations are clustered within a 9-kilobase (kb) BamHI genomic region of the MLL gene. By Southern blot hybridization using a 0.7-kb BamHI cDNA fragment of the MLL gene called MLL 0.7B, we have detected rearrangements of DNA from cell lines and patient material with an 11q23 translocation in this region. Northern blot analyses indicate that this gene has multiple transcripts, some of which appear to be lineage-specific. In normal pre-B cells, four transcripts of 12.5, 12.0, 11.5, and 2.0 kb are detected. These transcripts are also present in monocytoid cell lines with additional hybridization to a 5.0-kb transcript, indicating that expression of different-sized MLL transcripts may be associated with normal hematopoietic lineage development. In a cell line with a t(4;11), the expression of the 12.5-, 12.0-, and 11.5-kb transcripts is reduced, and there is evidence of three other altered transcripts of 11.5, 11.25, and 11.0 kb. Thus, these 11q23 translocations result in rearrangements of the MLL gene and may lead to altered function(s) of MLL and of other gene(s) involved in the translocation.

Mapping of the shortest region of overlap of deletions of the short arm of chromosome 9 associated with human neoplasia.

Deletions of the short arm of chromosome 9 with a minimum region of overlap at band 9p22 are frequently observed in acute lymphoblastic leukemia and in gliomas. They also occur at a lower frequency in lymphomas, melanomas, lung cancers, and other solid tumors. These deletions often include the entire interferon (IFN) gene cluster, which comprises about 26 interferon-alpha (IFNA), -omega (IFNW), and-beta-1 (IFNB1) interferon genes, as well as the gene for the enzyme methylthioadenosine phosphorylase (MTAP). By comparing microscopic deletions with the genes lost at the molecular level, we have determined the order of these genes on 9p to be telomere-IFNB1-IFNA/IFNW cluster-MTAP-centromere. In a few cell lines and in primary leukemia cells, we have observed deletions that have breakpoints within the IFN gene cluster and result in partial loss of the IFN genes. These partial deletions allowed us to determine the order of some genes or groups of genes within the IFNA/IFNW gene cluster. Our current results map the shortest region of overlap of these deletions in the various tumors to the region between the centromeric end of the IFNA/IFNW gene cluster and the MTAP gene locus.

Increased genetic instability of the common fragile site at 3p14 after integration of exogenous DNA.

We determined previously that the selectable marker pSV2neo is preferentially inserted into chromosomal fragile sites in human x hamster hybrid cells in the presence of an agent (aphidicolin) that induces fragile-site expression. In contrast, cells transfected without fragile-site induction showed an essentially random integration pattern. To determine whether the integration of marker DNA at fragile sites affects the frequency of fragile-site expression, the parental hybrid and three transfectants (two with pSV2neo integrated at the fragile site at 3p14.2 [FRA3B] and specific hamster fragile sites [chromosome 1, bands q26-31, or mar2, bands q11-13] and one with pSV2neo integrated at sites that are not fragile sites) were treated with aphidicolin. After 24 h the two cell lines with plasmid integration at FRA3B showed structural rearrangements at that site; these rearrangements accounted for 43%-67% of the total deletions and translocations observed. Structural rearrangements were not observed in the parental cell line. After 5 d aphidicolin treatment, the observed excess in frequency of structural rearrangements at FRA3B in the cell lines with pSV2neo integration at 3p14 over that in the two lines without FRA3B integration was less dramatic, but nonetheless significant. Fluorescent in situ hybridization (FISH) analysis of these cells, using a biotin-labeled pSV2neo probe, showed results consistent with the gross rearrangements detected cytogenetically in the lines with FRA3B integration; however, the pSV2neo sequences were frequently deleted concomitantly with translocations.(ABSTRACT TRUNCATED AT 250 WORDS)

Preferential integration of marker DNA into the chromosomal fragile site at 3p14: an approach to cloning fragile sites.

Fragile sites are specific regions of chromosomes that are prone to breakage. In cells cultured under conditions that induce fragile site expression, high levels of inter- and intrachromosomal recombination have been observed involving chromosomal bands containing fragile sites. To determine whether expression of specific fragile sites would facilitate preferential integration of exogenous DNA at these recombination hot spots, the vector pSV2Neo was transfected into a Chinese hamster-human somatic cell hybrid containing a derivative chromosome 3 as its only human component. Chromosome 3 contains a common fragile site at band 3p14.2 (FRA3B) that is induced by aphidicolin. Both cells induced to express FRA3B and the uninduced control cells were transfected with the pSV2Neo selectable plasmid. In situ hybridization of a biotin-labeled pSV2Neo probe to metaphase chromosomes revealed one to three integration sites in each stably transfected clone. Four of 13 clones transfected under conditions of FRA3B induction showed integration of pSV2Neo at 3p14; these clones also showed specific integration into hamster chromosome 1 and a rearranged chromosome characteristic of CHO cells (mar2). The 7 control clones, however, showed an apparently random pattern of pSV2Neo integration. Significant hybridization of pSV2Neo to both FRA3B and Chinese hamster chromosomes 1 and mar2 was seen in 100 cells from pooled colonies transfected after treatment with aphidicolin. These results suggest that preferential integration of marker DNA into human and Chinese hamster fragile sites occurs with exposure to aphidicolin. The nature of the DNA sequences at fragile sites is unknown and, despite a number of approaches, these sequences have not yet been isolated; our procedure may represent an approach to the cloning of fragile sites.

Mapping chromosome band 11q23 in human acute leukemia with biotinylated probes: identification of 11q23 translocation breakpoints with a yeast artificial chromosome.

Translocations involving chromosome 11, band q23, are frequent recurring abnormalities in human acute lymphoblastic and acute myeloid leukemia. We used 19 biotin-labeled probes derived from genes and anonymous cosmids for hybridization to metaphase chromosomes from leukemia cells that contained four translocations involving band 11q23: t(4;11)(q21;q23), t(6;11)(q27;q23), t(9;11)(p22;q23), and t(11;19)(q23;p13). The location of the cosmid probes relative to the breakpoint in 11q23 was the same in all translocations. Of the cosmid clones containing known genes, CD3D was proximal and PBGD, THY1, SRPR, and ETS1 were distal to the breakpoint on 11q23. Hybridization of genomic DNA from a yeast clone containing yeast artificial chromosomes (YACs), that carry 320 kilobases (kb) of human DNA including CD3D and CD3G genes, showed that the YACs were split in all four translocations. These results indicate that the breakpoint at 11q23 in each of these translocations occurs within the 320 kb encompassed by these YACs; whether the breakpoint within the YACs is precisely the same in the different translocations is presently unknown.

Experimental meningococcal infection in neonatal animals: models for mucosal invasiveness.

A more complete understanding of meningococcal disease has been hampered by lack of an appropriate animal model. We subjected 5-day-old guinea pigs, rats, and mice to intranasal challenge with meningococci and we measured rates of bacteremia as a marker of mucosal invasion. After a single intranasal instillation of 10(7) serotype 2 meningococci, positive blood cultures were found in 0% of guinea pigs, 16% of rats, and 39% of mice, and so mice were used for further studies. Death occurred in 4% of mice and was associated with a purulent leptomeningitis and ventriculitis. Forty percent of mice had nasopharyngeal colonization which increased to 65% with repeated injections. Carrier strains were avirulent, a nonserotype 2 disease strain had low invasiveness, and serotype 2 strains were most virulent. Iron dextran increased rates of bacteremia after challenge with serotype 2 strains. Adult animals were not susceptible to bacteremia after intranasal challenge. The neonatal mouse model fulfills most of the criteria for an appropriate experimental model of meningococcal disease.