Steering column for a motor vehicle

What is claimed is: 1. A steering column for a motor vehicle, which steering column is adjustable via a motor, wherein the steering column comprises: a supporting unit that is attachable to a body of the motor vehicle; an actuating unit held by the supporting unit, wherein the actuating unit includes a jacket unit in which a jacket tube is disposed; a steering spindle mounted in the jacket tube of the actuating unit such that the steering spindle is rotatable about a longitudinal axis; an adjusting drive that is connected to the supporting unit and to the actuating unit, wherein the adjusting drive is configured to telescopically adjust the jacket tube of the actuating unit relative to the supporting unit along the longitudinal axis, wherein the adjusting drive includes a threaded spindle that engages in a spindle nut, wherein the adjusting drive is operatively disposed between the jacket unit and the jacket tube of the actuating unit; and a drive unit configured to drive the threaded spindle rotationally relative to the spindle nut, wherein the drive unit is connected via a flexible drive connection to a gear unit that is attached to the jacket unit and is movable spatially relative to the drive unit, wherein the threaded spindle is connected to the jacket tube and is configured to translate relative to the gear unit. 2. The steering column of claim 1 wherein the flexible drive connection includes a flexible shaft. 3. The steering column of claim 1 wherein the gear unit comprises a gearwheel that is connected fixedly to and rotates with the spindle nut or the threaded spindle, wherein the gearwheel is rotatably drivable by the drive connection. 4. The steering column of claim 1 wherein the drive unit comprises a drive motor to which the drive connection is connected on an output side. 5. The steering column of claim 1 comprising an energy absorption device disposed between the gear unit and the supporting unit. 6. The steering column of claim 5 wherein the energy absorption device includes a first energy absorption element that is plastically deformable upon movement of the gear unit in a direction of an axis of the threaded spindle relative to the supporting unit. 7. The steering column of claim 6 wherein the gear unit includes a deformation member by which a second energy absorption element is plastically deformable upon movement of the gear unit relative to the supporting unit. 8. The steering column of claim 6 wherein the energy absorption device includes a switching device for coupling or decoupling the second energy absorption element between the gear unit and the supporting unit. 9. The steering column of claim 1 comprising a rupture element disposed between the gear unit and the supporting unit. 10. A steering column for a motor vehicle, which steering column is adjustable via a motor, wherein the steering column comprises: a supporting unit that is attachable to a body of the motor vehicle; an actuating unit held by the supporting unit; a steering spindle mounted in the actuating unit such that the steering spindle is rotatable about a longitudinal axis; an adjusting drive that is connected to the supporting unit and to the actuating unit, wherein the adjusting drive is configured to adjust the actuating unit relative to the supporting unit, wherein the adjusting drive includes a threaded spindle that engages in a spindle nut; a drive unit configured to drive the threaded spindle rotationally relative to the spindle nut, wherein the drive unit is connected via a flexible drive connection to a gear unit that is movable spatially relative to the drive unit; and an energy absorption device disposed between the gear unit and the actuating unit. 11. The steering column of claim 10 wherein the energy absorption device comprises an elongate, U-shaped guide profile. 12. The steering column of claim 11 wherein the elongate, U-shaped guide profile is attached directly to the supporting unit. 13. The steering column of claim 10 wherein a guide profile of the energy absorption device includes crash slots that are elongated in a direction of the longitudinal axis, wherein a deformation member extends into each of the crash slots. 14. The steering column of claim 13 wherein aside from a location of each crash slot where each deformation member is located prior to a crash event, a cross section of each deformation member is larger than a slot width of each crash slot such that movement of each deformation member relative to each crash slot requires deformation of the guide profile along a length of each crash slot. 15. The steering column of claim 10 configured such that in a crash event a crash force is transmitted via a casing tube of the actuating unit, the threaded spindle, and the spindle nut to the gear unit, wherein a shear bolt is configured to rupture upon the crash force exceeding a predefined limit value, wherein after the shear bolt ruptures the casing tube, the steering spindle, the threaded spindle, and the gear unit are configured to move relative to a guide profile of the energy absorption device and the drive unit. 16. The steering column of claim 10 wherein a guide profile of the energy absorption device includes a crash slot that is elongated in a direction of the longitudinal axis, wherein the crash slot tapers in a wedge-shaped manner, with side walls of the crash slot converging at an angle of less than or equal to 10°. 17. The steering column of claim 10 wherein a guide profile of the energy absorption device includes a first crash slot and a second crash slot that are elongated in a direction of the longitudinal axis, wherein outer elongate edges of the crash slots that are farthest from one another are parallel, wherein inner elongate edges of the crash slots that are closest to one another are transverse to one another. 18. The steering column of claim 10 wherein a guide profile of the energy absorption device includes a crash slot that is elongated in a direction of the longitudinal axis, wherein a first mandrel and a second mandrel extend into the crash slot. 19. The steering column of claim 18 wherein the second mandrel has a smaller cross section than the first mandrel. 20. The steering column of claim 18 the first mandrel is configured to be moved into and out of engagement with the crash slot such that the energy absorption device can provide two different levels of energy absorption.