The administration of 40° C heat-treatments was found to induce bivalent orientational instability and interlocking at male meiosis in the locust Locusta migratoria. Only the longest members of the complement showed orientational instability and these usually possessed single distally sited chiasmata, with near-maximal intercentromeric distances. An effect on the stability of spindle fibre microtubule association, or attachment to the chromosome, is considered to be a possible explanation of the behaviour found. Bipolar orientation was generally achieved prior to anaphase I so that chromosome segregation was usually normal. Diamphitelic bivalents provided the most common exception to this rule. They sometimes lagged at anaphase, with the separation of half-bivalents and the production of structures indistinguishable from lagging univalents. The bivalent interlocking also involved the longest members of the complement. Most combinations of rod/rod, rod/ring and ring/ring types of interlocking were found. Usually only two bivalents were interlocked in any one cell, although occasionally three were found interlocked. All types appeared to involve an effect on the regulation of chromosome pairing, although at least one of the cells found showed interlocking caused by the metaphase orientational instability. In most cells, interlocked bivalents showed stable orientation and this usually involved the unipolar orientation of each bivalent's two centromeres. Such configurations provide concrete support for the importance of physical tension in the maintenance of metaphase orientational stability. They lead to double non-disjunction at anaphase I. Interlocked bivalents showed normal congression to a mid-equatorial position with no tendency for the re-adjustment of arm ratios to equalise centromere distances from the poles. This behaviour is discussed in relation to spindle fibre dynamics and it is concluded that no hypothesis of congression currently available can satisfactorily explain all that we know of the behaviour of univalents, bivalents, multivalents and interlocked bivalents.