Heavy trafficking between the nucleus and the cytoplasm takes place in eucaryote cells. Various substrates, such as different forms of RNA and many nuclear proteins, must be exported into the cytoplasm. Other proteins, such as transcription factors and ribonucleoprotein particles, must be imported into the nucleus. Nuclear transport occurs through the nuclear pore complexes (NPCs), which are about 125 MDa in size (34). Whereas smaller molecules up to 20 to 60 kDa may passively diffuse through the NPCs into the nucleus, the import of larger substrates is generally receptor mediated (12). This import process depends on the presence of specific signal sequences within the substrate. Different types of import signals exist. One such signal consists of the so-called nuclear localization signals (NLSs), which are mainly characterized by clusters of basic amino acids, predominately lysines. Depending on the numbers of their charged clusters, the NLSs may be classified into monopartite and bipartite NLSs (8, 9). Several soluble factors of the classical nuclear protein import pathway have been identified so far, including the small GTPase Ran/TC4 (26, 30), importin α (16, 20, 45), importin β (1, 4, 14, 19, 39), and NTF2 (31, 36), which is involved in the import and export of Ran (41). Importin α functions as an adapter molecule by binding importin β via its amino-terminally located importin β binding (IBB) domain (13, 46) and by binding NLS-bearing proteins via its two NLS binding sites in the central area (5, 18). Importin β is the transport receptor that carries the importin α-NLS complex from the cytoplasm into the nuclear side of the NPC (17). Once inside the nucleus, importin β binds to RanGTP, which is generated within the nucleus by the chromatin-bound RanGDP/GTP exchange factor RCC1. This binding of importin β to RanGTP leads to the dissociation of the import complex (15). Whereas importin β is thought to return to the cytoplasm rapidly without other soluble factors, the export of importin α is mediated by its nuclear export factor CAS, which binds to importin α preferentially in the presence of RanGTP (24). In the cytoplasm, the importins are set free for another round of import by the concerted action of RanGAP1 and RanBP1. Only one gene coding for importin β has been identified in the organisms analyzed thus far. In contrast to what was found for importin β, several isoforms of importin α in humans have been described. These include importin α1/Rch1 (7, 45), importin α5/hSRP1 (6), importin α3/Qip1 (23, 42), importin α4/hSRP1γ (23, 32), importin α6 (23), and, here, the newly reported importin α7. Importin α7 is the human homologue of the recently identified mouse importin α-S2 (44). Based on the sequence similarity, the importin α proteins can be grouped into three subfamilies. Members of different subfamilies have about 50% sequence identity. Within one subfamily, the identity is at least 80%. Whereas several of these isoforms are also found in invertebrates, the yeast Saccharomyces cerevisiae has only one gene for importin α, SRP1. Why so many importin α isoforms exist in higher eucaryotes has not yet been definitely answered. Although there is some tissue specificity in the expression of these proteins (23, 32, 38, 44), most isoforms are expressed within the same tissues. Initial data indicate that there may be distinct substrate specificities of different importin α family members (11, 28, 33, 43). However, other data show that different importin α proteins can interact with the same substrate (37, 38). We compared all of the ubiquitously expressed human importin α proteins, Xenopus importin α2, and yeast SRP1p in their efficiencies to promote the nuclear import of different substrates. When testing only one substrate per assay, we found that most substrates (NLS-bovine serum albumin [BSA], nucleoplasmin, P/CAF, and hnRNP K) were imported by all importin α proteins with only marginal differences. The exception was the nuclear import of RCC1, which was efficient only with importin α3, not with other isoforms. If two substrates are offered at the same time, the various importin α proteins show striking differences in their substrate-specific import efficiencies.