Recent experiments on BEC [Science, 269(5221), 198 (1995); Phys. Rev. Lett. 75, 3969 (1995); 77, 4984 (1996)] were performed with atomic gases in traps, where atoms are held together by the magnetic field and cooled down to nano-Kelvin temperatures using laser and evaporative cooling. The trapped atoms are characterized by some momentum distribution, whose width is determined by the temperature of the gas. When the Bose-Einstein transition takes place, the momentum distribution suddenly narrows, which means that a large number of atoms now occupy the lowest energy state. Until these experiments the BEC was observed only in condensed state systems (liquid He), where atoms interact strongly with each other. The recent achievement is remarkable because the BEC is obtained in the gas phase, where the interaction between atoms is relatively small. However, this interaction is crucial for the formation of the condensate. According to the standard theoretical picture of the BEC, the condensate is possible only when the atoms repel each other. Microscopically, this means that the atom-atom scattering length must be positive. If the atom-atom scattering length is negative, the atoms attract each other and a stable BEC is not possible. In spite of this notion, it was claimed recently [Phys. Rev. Lett. 75, 1687 (1995); 78, 985 (1997)] that BEC also takes place in the gas of lithium atoms, where the scattering length is negative. So far there has been no unambiguous interpretation of this result.