While most methods are now focused on identifying the precise molecular cause of disease, indirect tests can be quite useful, particularly for mapping causes of a disease in a family. For example, testing for markers such as single nucleotide polymorphisms (SNPs) or short tandem repeats (STRs, which are 2–5 base long repetitive elements with varying numbers of repeats) that are found throughout the genome can be extremely useful as a way to identify likely causal genes, particularly in diseases where multiple possible causal genes have been implicated. For example, in hereditary spherocytosis a number of genes including ANK1, SPTB, SPTA, SLC4A1, and EBP42 are implicated in the disease. Many of these genes are quite large and while sequencing a panel of genes is certainly possible, in a large family, the use of either SNP-based methods or other markers such as STRs can identify the likely causal locus to help focus targeted sequencing efforts. These methods are commonly used for diagnostic mapping in resource-poor settings where whole-genome sequencing (WGS) methods may not be available and these methods can also be extremely useful in other settings. For example, if a family is being followed with a known disease, but no coding mutations are identified on targeted sequencing, these approaches can help validate that there is linkage to a specific gene and they may assist in the efforts to identify mutations in regulatory regions of the implicated gene. Specifically, segregation of markers that are in linkage with the causal mutation should only be found in affected family members and would suggest that the causal mutation is located nearby. These methods are also commonly used as an initial screen in families where possible cancer predisposition syndromes may exist and can help focus in-depth analysis on certain regions of the genome. Even in cases where whole-exome or -genome sequencing is performed, linkage can provide an excellent indirect approach to focus on marker genes that segregate appropriately in individuals who have a particular disease.

Fluorescent in situ hybridization (FISH) was developed in the 1980s and uses fluorescently labeled DNA probes to query whether entire chromosomes or parts of a chromosome may be duplicated or deleted in cells. The fluorescently labeled DNA probes are complementary to the region of interest on a chromosome and therefore specifically hybridize only to this region and not to others. FISH is commonly used to assess for gain or loss of chromosomes or large parts of chromosomes in patients with hematologic malignancies. Typically, a numbe...